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References

Published online by Cambridge University Press:  09 December 2021

Karl F. Nordstrom
Affiliation:
Rutgers University, New Jersey
Nancy L. Jackson
Affiliation:
New Jersey Institute of Technology
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References

Abel, N., Gorddard, R., Harman, B., Leitch, A., Langridge, J., Ryan, A., and Heyenga, S. (2011). Sea level rise, coastal development and planned retreat: analytical framework, governance principles and an Australian case study. Environmental Science and Policy 14: 279288.Google Scholar
Abraham, R. (2000). Die Renaturierung des Polders Friedrichshagen – zweites Deichrückbauprojekt in Ostvorpommern. Naturschutzarbeit in Mecklenburg-Vorpommern 43: 7073.Google Scholar
Aceti, S. and Avendaño, C. (1999). California’s coastal communities organize to increase state funding for beaches. Shore and Beach 67(4): 36.Google Scholar
Acosta, A., Carranza, M. L., and Izzi, C. F. (2009). Are there habitats that contribute best to plant species diversity in coastal dunes? Biodiversity and Conservation 18: 10871098.Google Scholar
Adriani, M. J. and Terwindt, J. H. J. (1974). Sand Stabilization and Dune Building. Rijkswaterstaat Communications 19. The Hague: Rijkswaterstaat.Google Scholar
Alexander, D. E. (2013). Resilience and disaster risk reduction: an etymological journey. Natural Hazards and Earth System Sciences 13: 27072716.Google Scholar
Alexandrakis, G., Ghionis, G., Poulos, S. E., and Kampanis, N. A. (2013). Greece. In Pranzini, E. and Williams, A. (Eds.), Coastal Erosion and Protection in Europe. London: Routledge, pp. 355377.Google Scholar
Almarshed, B., Figlus, J., Miller, J., and Verhagen, J. (2020). Innovative coastal risk reduction through hybrid design: combining sand cover and structural defenses. Journal of Coastal Research 36: 174188.Google Scholar
Altomare, C. and Gentile, G. M. (2013). An innovative methodology for the re-naturalization process of a shingle beach. Journal of Coastal Research SI65: 14561460.Google Scholar
Alves, B., Ballester, R., Rigall-I-Torrent, R., Ferreira, Ó., and Benavente, J. (2017). How feasible is coastal management? A social benefit analysis of a coastal destination in SW Spain. Tourism Management 60: 188200.Google Scholar
Aminti, P., Cipriani, L. E., and Pranzini, E. (2003). Back to the beach: converting seawalls into gravel. In Goudas, C. L., Katsiaris, G., May, V., et al. (Eds.), Soft Shore Protection. Dordrecht: Kluwer Academic Publishers, pp. 261274.Google Scholar
Anders, F. J. and Leatherman, S. P. (1987). Effects of off-road vehicles on coastal foredunes at Fire Island, New York, USA. Environmental Management 11: 4552.Google Scholar
Anderson, P. and Romeril, M. G. (1992). Mowing experiments to restore species-rich sward on sand dunes in Jersey, Channel Islands, GB. In Carter, R. W. G., Curtis, T. G. F., and Sheehy-Skeffington, M. J. (Eds.), Coastal Dunes: Geomorphology, Ecology and Management for Conservation. Rotterdam: A.A. Balkema, pp. 219234.Google Scholar
Andrade, C., Lira, F., Pereira, M. T., Ramos, R., Guerreiro, J., and Feirtas, M. C. (2006). Monitoring the nourishment of Santo Amaro estuarine beach (Portugal). Journal of Coastal Research SI39: 776782.Google Scholar
Andrews, C. (2016). Local fiscal impacts of Hurricane Sandy. In O’Neil, K. M. and van Abs, D. J. (Eds.), Taking Chances: The Coast after Hurricane Sandy. New Brunswick, NJ: Rutgers University Press, pp. 190207.Google Scholar
Anfuso, G. and Gracia, F.-J. (2005). Morphodynamic characteristics and short-term evolution of a coastal sector in SW Spain: implications for coastal erosion management. Journal of Coastal Research 21: 11391153.Google Scholar
Anthony, E. J. and Cohen, O. (1995). Nourishment solutions to the problem of beach erosion in France: the case of the French Riviera. In Healy, M. G. and Doody, J. P. (Eds.), Directions in European Coastal Management. Cardigan: Samara Publishing, pp. 199212.Google Scholar
Anthony, E. J., Vanhee, S., and Ruz, M.-H. (2007). An assessment of the impacts of experimental brushwood fences on foredune sand accumulation based on digital elevation models. Ecological Engineering 31: 4146.Google Scholar
Anthony, E. J., Cohen, O., and Sabatier, F. (2011). Chronic offshore loss of nourishment on Nice beach, French Riviera: a case of over-nourishment of a steep beach. Coastal Engineering 58: 374383.Google Scholar
Anthony, E. J. and Sabatier, F. (2013). France. In Pranzini, E. and Williams, A. (Eds.), Coastal Erosion and Protection in Europe. London: Routledge, pp. 227253.Google Scholar
Anthony, E. J., Marriner, N., and Morhange, C. (2014). Human influence and the changing geomorphology of Mediterranean deltas and coasts over the last 6000 years: from progradation to destruction phase? Earth-Science Reviews 139: 336361.Google Scholar
Antunes do Carmo, J., Schreck Reis, C., and Freitas, H. (2010). Working with nature by protecting sand dunes: lessons learned. Journal of Coastal Research 26: 10681078.Google Scholar
Arba, P., Arisci, A., de Waele, A., et al. (2002). Environmental impact of artificial nourishment of the beaches of Cala Gonone (Central – East Sardinia). Littoral 2002: 465468.Google Scholar
Archetti, R. (2009). Quantifying the evolution of a beach protected by low crested structures using video monitoring. Journal of Coastal Research 25: 884899.Google Scholar
Ardeshiri, A., Swait, J., Heagney, E. C., and Kovac, M. (2019). Willingness-to-pay for coastline protection in New South Wales: beach preservation management and decision making. Ocean & Coastal Management 178: 104805.Google Scholar
Arens, S. M. and Wiersma, J. (1994). The Dutch foredunes: inventory and classification. Journal of Coastal Research 10: 189202.Google Scholar
Arens, S. M., Jungerius, P. D., and van der Meulen, F. (2001). Coastal dunes. In Warren, A. and French, J. R. (Eds.), Habitat Conservation: Managing the Physical Environment. London: John Wiley & Sons, pp. 229272.Google Scholar
Arens, S. M., Slings, Q., and de Vries, C. N. (2004). Mobility of a remobilised parabolic dune in Kennemerland, The Netherlands. Geomorphology 59: 175188.Google Scholar
Arens, S. M., Geelen, L., Slings, R., and Wondergem, H. (2005). Restoration of dune mobility in the Netherlands. In Herrier, J.-L., Mees, J., Salman, A., et al. (Eds.), Dunes and Estuaries 2005 – International Conference on Nature Restoration Practices in European Coastal Habitats. Koksijde, Belgium: VLIZ Special Publication, pp. 129138.Google Scholar
Arens, S. M., Mulder, J. P. M., Slings, Q. L., Geelen, L. H. W. T., and Damsma, P. (2013a). Dynamic dune management, integration objectives of nature development and coastal safety: examples from the Netherlands. Geomorphology 199: 205213.Google Scholar
Arens, S. M., Slings, Q. L., Geelen, L. H. W. T., and van der Hagen, H. G. J. M. (2013b). Restoration of dune mobility in The Netherlands. In Martínez, M. L., Gallego-Fernández, J. B., and Hesp, P. A. (Eds.), Restoration of Coastal Dunes. New York: Springer, pp. 107124.Google Scholar
Arens, S. M., de Vries, S., Geelen, L. H. W. T., Ruessink, G., van der Hagen, H. G. J. M., and Groenendijk, D. (2020). Comment on Is “remobilisation” nature restoration or nature destruction? A commentary by I. Delgado-Fernandez, R. G. D. Davidson-Arnott & P. A. Hesp. Journal of Coastal Conservation 24: 17.Google Scholar
Ariza, E. (2011). An analysis of beach management framework in Spain. Study case: the Catalonian coast. Journal of Coastal Conservation 15: 445455.Google Scholar
Ariza, E., Sarda, R., Jimenez, J. A., Mora, J., and Avila, C. (2008). Beyond performance assessment measurements for beach management: application to Spanish Mediterranean beaches. Coastal Management 36: 4766.Google Scholar
Ariza, E., Lindeman, K. C., Mozumder, P., and Suman, D. O. (2014). Beach management in Florida: assessing stakeholder perceptions on governance. Ocean & Coastal Management 96: 8293.Google Scholar
Arler, F. (2000). Aspects of landscape or nature quality. Landscape Ecology 15: 291302.Google Scholar
Armstrong, J. W., Staude, C. P., Thom, R. M., and Chew, K. K. (1976). Habitats and relative abundances of intertidal macrofauna at five Puget Sound beaches in the Seattle area. Syesis 9: 277290.Google Scholar
Armstrong, S. B., Lazarus, E. D., Limber, P. W., Goldstein, E. B., Thorp, C., and Ballinger, R. C. (2016). Indications of a positive feedback between coastal development and beach erosion. Earths Future 4: 626635.Google Scholar
Aronson, J., Floret, C., Le Floc’h, E., Ovalle, C., and Pontanier, R. (1993). Restoration and rehabilitation of degraded ecosystems in arid and semi-arid lands. I. A view from the south. Restoration Ecology 1: 817.Google Scholar
Aronson, J., Dhillion, S., and Le Floc’h, E. (1995). On the need to select an ecosystem of reference, however imperfect: a reply to Pickett and Parker. Restoration Ecology 3: 13.Google Scholar
Arthurton, R. (1998). Resource, evaluation and net benefit. In Hooke, J. (Ed.), Coastal Defense and Earth Science Conservation. Bath: The Geological Society, pp. 151161.Google Scholar
Austin, M. J. and Masselink, G. (2006). Swash-groundwater interaction on a steep gravel beach. Continental Shelf Research 26: 25032519.Google Scholar
Autorita’ di Bacino Del Fiume Arno. (1994). L’evoluzione e la dinamica del litorale prospiciente i bacini dell’Arno e del Serchio e i problemi di erosione della costa, 3. Autorità di Bacino dell’Arno e del Serchio.Google Scholar
Avis, A. M. (1995). An evaluation of the vegetation developed after artificially stabilizing South African coastal dunes with indigenous species. Journal of Coastal Conservation 1: 4150.Google Scholar
Baeyens, G. and Martínez, M. L. (2004). Animal life on coastal dunes: from exploitation and prosecution to protection and monitoring. In Martínez, M. L. and Psuty, N. P. (Eds.), Coastal Dunes, Ecology and Conservation. Berlin: Springer-Verlag, pp. 279296.Google Scholar
Balestri, E., Vallerini, F., and Lardicci, C. (2006). A qualitative and quantitative assessment of the reproductive litter from Posidonia oceanica accumulated on a sand beach following a storm. Estuarine, Coastal and Shelf Science 66: 3034.Google Scholar
Balestri, E., Vallerini, F., Seggiani, M., et al. (2019). Use of bio-containers from seagrass wrack with nursery planting to improve the eco-sustainability of coastal habitat restoration. Journal of Environmental Management 251: 109604.Google Scholar
Balletto, J. H., Heimbuch, M. V., and Mahoney, H. K. (2005). Delaware Bay salt marsh restoration: mitigation for a power plant cooling water system in New Jersey, USA. Ecological Engineering 25: 204213.Google Scholar
Barbier, E. B., Hacker, S. D., Kennedy, C., Koch, E. W., Stier, A. C., and Silliman, B. R. (2011). The value of estuarine and coastal ecosystem services. Ecological Monographs 81: 169193.Google Scholar
Barbour, E. and Kueppers, L. M. (2012). Conservation and management of ecological systems in a changing California. Climatic Change 111: 135163.Google Scholar
Barbour, M. G. (1990). The coastal beach plant syndrome. In Davidson-Arnott, R. G. D. (Ed.), Proceedings of the Symposium on Coastal Sand Dunes. Ottawa: National Research Council Canada, pp. 197214.Google Scholar
Barnard, P. L., Erikson, L. H., Foxgrover, A. C., et al. (2019). Dynamic flood modeling essential to assess the coastal impacts of climate change. Scientific Reports 9.Google Scholar
Barragán Muñoz, J. M. (2003). Coastal zone management in Spain (1975–2000). Journal of Coastal Research 19: 314325.Google Scholar
Barrett, C. B. and Grizzle, R. (1999). A holistic approach to sustainability based on pluralism stewardship. Environmental Ethics 21: 2342.Google Scholar
Barton, M. E. (1998). Geotechnical problems with the maintenance of geological exposures in clay cliffs subject to reduced erosion rates. In Hooke, J. (Ed.), Coastal Defense and Earth Science Conservation. Bath: The Geological Society, pp. 3245.Google Scholar
Basco, D. R. (1998). The economic analysis of “soft” versus “hard” solutions for shore protection: an example. In Coastal Engineering: Proceedings of the Twenty-Sixth Coastal Engineering Conference. New York: American Society of Civil Engineers, pp. 14491460.Google Scholar
Basco, D. R. and Pope, J. (2004). Groin functional design guidance from the Coastal Engineering Manual. Journal of Coastal Research SI33: 121130.Google Scholar
Baye, P. (1990). Ecological history of an artificial foredune ridge on a northeastern barrier spit. In Davidson-Arnott, R. G. D. (Ed.), Proceedings of the Symposium on Coastal Sand Dunes. Ottawa: National Research Council Canada, pp. 389403.Google Scholar
Beachler, K. E. and Mann, D. W. (1996). Long range positive effects of the Delray beach nourishment program. In Coastal Engineering 1996: Proceedings of the Twenty-Fifth International Conference. New York: American Society of Civil Engineers, pp. 46134620.Google Scholar
Beatley, T. (1991). Protecting biodiversity in coastal environments: introduction and overview. Coastal Management 19: 119.Google Scholar
Beck, T. M. and Wang, P. (2019). Morphodynamics of barrier-inlet systems in the context of regional sediment management, with case studies from west-central Florida, USA. Ocean & Coastal Management 177: 3151.Google Scholar
Belcher, C. R. (1977). Effect of sand cover on the survival and vigor of Rosa rugosa Thunb. International Journal of Biometeorology 21: 276280.Google Scholar
Bell, J., Sauders, M. I., Leon, J. X., et al. (2014). Maps, laws and planning policy: working with biophysical and spatial uncertainty in the case of sea level rise. Environmental Science and Policy 44: 247257.Google Scholar
Bell, M. C. and Fish, J. D. (1996). Fecundity and seasonal changes in reproductive output of females of the gravel beach amphipod Pectenogammarus planicrurus. Journal of the Marine Biological Association of the United Kingdom 76: 3755.Google Scholar
Benavente, J., Anfuso, G., Del Rio, L., Gracia, F. J., and Reyes, J. L. (2006). Evolutive trends of nourished beaches in SW Spain. Journal of Coastal Research SI39: 765769.Google Scholar
Benedet, L., Finkl, C. W., Campbell, T., and Klein, A. (2004). Predicting the effect of beach nourishment and cross-shore sediment variation on beach morphodynamic assessment. Coastal Engineering 51: 839861.Google Scholar
Benedet, L., Finkl, C. W., and Dobrochinski, J. P. H. (2013). Optimization of nearshore dredge pit design to reduce impacts on adjacent beaches. Journal of Coastal Research 29: 519525.Google Scholar
Bennett, A. F. (1991). Roads, roadsides and wildlife conservation: a review. In Saunders, D. A. and Hobbs, R. J. (Eds.), Nature Conservation 2: The Role of Corridors. Chipping Norton, NSW: Surrey Beatty and Sons, pp. 7184.Google Scholar
Bergillos, R. J., Ortega-Sánchez, M., Masselink, G., and Losada, M. A. (2016). Morpho-sedimentary dynamics of a micro-tidal mixed sand and gravel beach, Playa Granada, southern Spain. Marine Geology 379: 2838.Google Scholar
Berkowitz, J. F., van Zomeren, C. M., and Priestas, A. M. (2018). Potential color change dynamics of beneficial use sediments. Journal of Coastal Research 34: 11491156.Google Scholar
Berlanga-Robles, C. A. and Ruiz-Luna, A. (2002). Land use mapping and change detection in the coastal zone of northwest Mexico using remote sensing techniques. Journal of Coastal Research 18: 514522.Google Scholar
Berry, A., Fahey, S., and Meyers, N. (2013). Changing of the guard: adaptation options that maintain ecologically resilient sandy beach ecosystems. Journal of Coastal Research 29: 899908.Google Scholar
Bertness, M. D. and Callaway, R. (1994). Positive interactions in communities. Trends in Ecology and Evolution 9: 191193.Google Scholar
Bertoni, D. and Sarti, G. (2011). On the profile evolution of three artificial pebble beaches at Marina di Pisa, Italy. Geomorphology 130: 244254.Google Scholar
Bessette, S. R., Hicks, D. W., and Fierro-Cabo, A. (2018). Biological assessment of dune restoration in south Texas. Ocean & Coastal Management 163: 466477.Google Scholar
Best, P. N. (2003). Shoreline management areas: a tool for shoreline ecosystem management. Puget Sound Notes 47: 811.Google Scholar
Biel, R. G., Hacker, S. D., Ruggiero, P., Cohn, N., and Seabloom, E. W. (2017). Coastal protection and conservation on sandy beaches and dunes: context-dependent tradeoffs in ecosystem service supply. Ecosphere 8: e01791.Google Scholar
Bilhorn, T. W., Woodard, D. W., Otteni, L. C., Dahl, B. E., and Baker, R. L. (1971). The Use of Grasses for Dune Stabilization along the Gulf Coast with Initial Emphasis on the Texas Coast. Report GURC-114. Galveston, TX: Gulf Universities Research Consortium.Google Scholar
Bilkovic, D. M., Mitchell, M., Mason, P., and Duhring, K. (2016). The role of living shorelines as estuarine habitat conservation strategies. Coastal Management 44: 161174.Google Scholar
Bilodeau, A. L. and Bourgeois, R. P. (2004). Impact of beach restoration on the deep-burrowing ghost shrimp Callichirus islagrande. Journal of Coastal Research 20: 931936.Google Scholar
Binder, S. B., Baker, C. K., and Barile, J. P. (2015). Rebuild or relocate? Resilience and postdisaster decision-making after Hurricane Sandy. American Journal of Community Psychology 56: 180196.Google Scholar
Bishop, M. J., Peterson, C. H., Summerson, H. C., Lenihan, H. S., and Grabowski, J. H. (2006). Deposition and long-shore transport of dredge spoils to nourish beaches: impacts on benthic infauna of an ebb-tidal delta. Journal of Coastal Research 22: 530546.Google Scholar
Bissett, S. N., Zinnert, J. C., and Young, D. R. (2014). Linking habitat with associations of woody vegetation and vines on two Mid-Atlantic barrier islands. Journal of Coastal Research 30: 843850.Google Scholar
Bitan, M. and Zviely, D. (2020). Sand beach nourishment: experience from the Mediterranean Coast of Israel. Journal of Marine Science and Engineering 8: 273.Google Scholar
Blackstock, T. (1985). Nature conservation within a conifer plantation on a coastal dune system, Newborough Warren, Anglesey. In Doody, P. (Ed.), Sand Dunes and Their Management. Peterborough: Nature Conservancy Council, pp. 145149.Google Scholar
Blanco, B., Whitehouse, R., Holmes, P., and Clarke, S. (2003). Mixed beaches (sand/gravel): process understanding and implications for management. In Proceedings of the 38th DEFRA Flood and Coastal Management Conference. London: Department for Environment, Food and Rural Affairs, pp. 3.13.12.Google Scholar
Blindow, I., Gauger, D., and Ahlhaus, M. (2017). Management regimes in a coastal heathland – effects on vegetation, nutrient balance, biodiversity and gain of bioenergy. Journal of Coastal Conservation 21: 273288.Google Scholar
Blott, S. J. and Pye, K. (2004). Morphological and sedimentological changes on an artificially nourished beach, Lincolnshire, UK. Journal of Coastal Research 20: 214233.Google Scholar
Bobbink, R., Hornung, M., and Roelofs, J. G. M. (1998). The effects of air-borne nitrogen pollutants on species diversity in natural and semi-natural European vegetation. Journal of Ecology 86: 717738.Google Scholar
Bocamazo, L. M., Grosskopf, W. G., and Buonuiato, F. S. (2011). Beach nourishment, shoreline change, and dune growth at Westhampton Beach, New York, 1996–2009. Journal of Coastal Research SI59: 181191.Google Scholar
Bonte, D., Maelfait, J.-P., and Hoffmann, M. (2000). The impact of grazing on spider communities in a mesophytic calcareous dune grassland. Journal of Coastal Conservation 6: 135144.Google Scholar
Boon, J. D. (2012). Evidence of sea level acceleration at U.S. and Canadian tide stations, Atlantic Coast, North America. Journal of Coastal Research 28: 14371445.Google Scholar
Boorman, L. A. (1989). The grazing of British sand dune vegetation. Proceedings of the Royal Society of Edinburgh 96B: 7588.Google Scholar
Borja, A. and Elliott, M. (2019). So when will we have enough papers on microplastics and ocean litter? Marine Pollution Bulletin 146: 312316.Google Scholar
Borsje, B. W., van Wesenbeeck, B. K., Dekker, F., et al. (2011). How ecological engineering can serve in coastal protection. Ecological Engineering 37: 113122.Google Scholar
Bossard, V. and Nicolae Lerma, A. (2020). Geomorphologic characteristics and evolution of managed dunes on the South West Coast of France. Geomorphology 367: 107312.Google Scholar
Bossuyt, B., Cosyns, E., and Hoffmann, M. (2007). The role of seed banks in the restoration of dry acidic dune grassland after burning of Ulex europaeus scrub. Applied Vegetation Science 10: 131138.Google Scholar
Bourman, R. P. (1990). Artificial beach progradation by quarry waste disposal at Rapid Bay, South Australia. Journal of Coastal Research SI6: 6976.Google Scholar
Bowman, D., Manor-Samsonov, N., and Golik, A. (1998). Dynamics of litter pollution on Israeli Mediterranean beaches: a budgetary, litter flux approach. Journal of Coastal Research 14: 418432.Google Scholar
Brampton, A. H. (1998). Cliff conservation and protection: methods and practices to resolve conflicts. In Hooke, J. (Ed.), Coastal Defense and Earth Science Conservation. Bath: The Geological Society, pp. 2131.Google Scholar
Bray, M. and Hooke, J. (1998). Spatial perspectives in coastal defence and conservation strategies. In Hooke, J. (Ed.), Coastal Defence and Earth Science Conservation. Bath: The Geological Society, pp. 115132.Google Scholar
Brennan, J. (2011). Powel Shoreline Restoration Design Project: Final Report. Bainbridge Island, WA: Bainbridge Island Land Trust.Google Scholar
Breton, F. and Esteban, P. (1995). The management and recuperation of beaches in Catalonia. In Healy, M. G. and Doody, J. P. (Eds.), Directions in European Coastal Management. Cardigan: Samara Publishing Ltd., pp. 511517.Google Scholar
Breton, F., Clapés, J., Marqués, A., and Priestly, G. K. (1996). The recreational use of beaches and consequences for the development of new trends in management: the case of the beaches in the Metropolitan Region of Barcelona. Ocean & Coastal Management 32: 153180.Google Scholar
Breton, F., Esteban, P., and Miralles, E. (2000). Rehabilitation of metropolitan beaches by local administrations in Catalonia: new trends in sustainable coastal management. Journal of Coastal Conservation 6: 97106.Google Scholar
Bridges, T. S., Wagner, P. W., Burks-Copes, K. A., et al. (2015). Use of Natural and Nature-Based Features (NNBF) for Coastal Resilience. ERDC SR-15-1. Vicksburg, MS: U.S. Army Engineer Research and Development Center.Google Scholar
Brock, K. A., Reece, J. S., and Ehrhart, L. M. (2009). The effects of artificial beach nourishment on marine turtles: differences between Loggerhead and green turtles. Restoration Ecology 17: 297307.Google Scholar
Brodie, K., Conery, I., Cohn, N., Spore, N., and Palmsten, M. (2019). Spatial variability of coastal foredune evolution, Part A: timescales of months to years. Journal of Marine Science and Engineering 7(124): 128.Google Scholar
Brooks, S. M. and Spencer, T. (2010). Temporal and spatial variations in recession rates and sediment release from soft rock cliffs, Suffolk, coast, UK. Geomorphology 124: 2641.Google Scholar
Broome, S. W., Seneca, E. D., Woodhouse, W. W., and Griffin, C. (1982). Building and Stabilizing Coastal Dunes with Vegetation. UNC-SG-82-05. Raleigh: North Carolina University Sea Grant.Google Scholar
Brown, A. C. (1996). Behavioural plasticity as a key factor in the survival and evolution of the macrofauna on exposed sandy beaches. Revista Chilena de Historia Natural 69: 469474.Google Scholar
Brown, A. C. and McLachlan, A. (2002). Sandy shores ecosystems and the threats facing them: some predictions for the year 2025. Environmental Conservation 29: 6277.Google Scholar
Brown, A. C., Nordstrom, K. F., McLachlan, A., Jackson, N. L., and Sherman, D. J. (2008). The future of sandy shores. In Polunin, N. (Ed.), The Waters, Our Future. Prospects for the Integrity of Aquatic Ecosystems. Cambridge: Cambridge University Press, pp. 263280.Google Scholar
Brown, J. M., Phelps, J. J. C., Barkwith, A., Hurst, M. D., Ellis, M. A., and Plater, A. J. (2016). The effectiveness of beach mega-nourishment, assessed over three management epochs. Journal of Environmental Management 184: 400408.Google Scholar
Browne, M. A. and Chapman, M. G. (2011). Ecologically informed engineering reduces loss of intertidal biodiversity on artificial shores. Environmental Science and Technology 45: 82048207.Google Scholar
Brunbjerg, A. K., Jørgensen, G. P., Nielsen, K. M., Pedersen, M. L., Svenning, J.-C., and Ejrnaes, R. (2015). Disturbance in dry coastal dunes in Denmark promotes diversity of plants and arthropods. Biological Conservation 182: 243253.Google Scholar
Brutsché, K. E., Wang, P., Rosati, J. D., and Beck, T. M. (2015). Evolution of a swash zone berm nourishment and influence of berm elevation on the performance of beach-nearshore nourishments along Perdido Key, Florida, USA. Journal of Coastal Research 31: 964977.Google Scholar
Buchanan, J. K. (1995). Managing heritage coasts. In Salman, A. H. P. M., Berends, H., and Bonazountas, M. (Eds.), Coastal Management and Habitat Conservation. Leiden: EUCC, pp. 153159.Google Scholar
Buckley, E. C. B., Hilton, M. J., Konlechner, T. M., and Lord, J. M. (2016). Downwind sedimentation and habitat development following Ammophila arenaria removal and dune erosion, Mason Bay, New Zealand. Journal of Coastal Research SI75: 268272.Google Scholar
Burger, J., Howe, M. A., Hahn, D. C., and Chase, J. (1977). Effects of tide cycles on habitat selection and habitat partitioning by migrating shorebirds. Auk 4: 743758.Google Scholar
Burger, J., O’Neill, K. M., Handel, S. N., Hensold, B., and Ford, G. (2017). The shore is wider than the beach: ecological planning solutions to sea level rise for the Jersey shore USA. Landscape and Urban Planning 157: 512522.Google Scholar
Burgess, K., Hunt, P., Cali, M., Jay, H., and Campbell, D. (2016). Planning for change on the Lincolnshire coast. In Baptiste, A. (Ed.), Coastal Management: Changing Coast, Changing Climate, Changing Minds. International Coastal Management Conference. London: ICE Publishing, pp. 425436.Google Scholar
Burke, S. M. and Mitchell, N. (2007). People as ecological participants in ecological restoration. Restoration Ecology 15: 348350.Google Scholar
Burkitt, J. and Wootton, L. (2011). Effects of disturbance and age of invasion on the impact of invasive sand sedge, Carex kobomugi, on native dune plant populations in New Jersey’s coastal dunes. Journal of Coastal Research 27: 182193.Google Scholar
Caetano, C. H. S., Cardoso, R. S., Veloso, V. G., and Silva, E. S. (2006). Population biology and secondary production of Excirolana braziliensis (Isopoda: cirolanidae) in two sandy beaches of southeastern Brazil. Journal of Coastal Research 22: 825835.Google Scholar
Cahoon, L. B., Carey, E. S., and Blum, J. E. (2012). Benthic microalgal biomass on ocean beaches: effects of sediment grain size and beach nourishment. Journal of Coastal Research 28: 853859.Google Scholar
Caldwell, J. M. (1966). Coastal processes and beach erosion. Journal of the Society of Civil Engineers 53: 142157.Google Scholar
Callaway, R. M. (1995). Positive interactions among plants. Botanical Review 61: 306349.Google Scholar
Cammelli, C., Jackson, N. L., Nordstrom, K. F., and Pranzini, E. (2006). Assessment of a gravel-nourishment project fronting a seawall at Marina di Pisa, Italy. Journal of Coastal Research SI39: 770775.Google Scholar
Campbell, T. and Benedet, L. (2007). A dedicated issue on the “storm protective value of coastal restoration.” Shore and Beach 75(1): 23.Google Scholar
Capobianco, M., Hanson, H., Larson, M., et al. (2002). Nourishment design and evaluation: applicability of model concepts. Coastal Engineering 47: 113135.Google Scholar
Caputo, C., Chiocci, F. L., Ferrante, A., La Monica, G. B., Landini, B., and Pugliese, F. (1993). La ricostituzione dei litorali in erosione mediante ripascimento artificiale e il problema del reperimento degli inerti. In La difesa dei litorali in Italia. Roma: Edizioni delle Autonomie, pp. 121151.Google Scholar
Carro, I., Seijo, L., Nagy, G. J., Lagos, X., and Gutiérez, O. (2018). Building capacity on ecosystem-based adaptation strategy to cope with extreme events and sea-level rise on the Uruguayan coast. International Journal of Climate Change Strategies and Management 10: 504522.Google Scholar
Carter, R. W. G. and Orford, J. D. (1984). Coarse clastic barrier beaches: a discussion of the distinctive dynamic and morphosedimentary characteristics. Marine Geology 60: 377389.Google Scholar
Castelle, B., Turner, I. L., Bertin, X., and Tomlinson, R. (2009). Beach nourishments at Coolangatta Bay over the period 1987–2005. Coastal Engineering 56: 940950.Google Scholar
Castelle, B., Laporte-Fauret, Q., Marieu, V., et al. (2019). Nature-based solution along high-energy eroding sandy coasts: preliminary tests on the reinstatement of natural dynamics in reprofiled coastal dunes. Water 11: 2518.Google Scholar
Castillo, S. A. and Moreno-Casasola, P. (1996). Coastal sand dune vegetation: an extreme case of species invasion. Journal of Coastal Conservation 2: 1322.Google Scholar
Castley, J. G., Bruton, J.-S., Kerley, G. I. H., and McLachlan, A. (2001). The importance of seed dispersal in the Alexandria coastal dune field, South Africa. Journal of Coastal Conservation 7: 5770.Google Scholar
Catma, S. (2020). Non-market valuation of beach quality: using spatial hedonic price modeling in Hilton Head Island, SC. Marine Policy 115: 103866.Google Scholar
Cazenave, A. and Le Cozannet, G. (2013). Sea level rise and its coastal impacts. Earth’s Future 2: 1534.Google Scholar
Cerra, J. F. (2017). Emerging strategies for voluntary urban ecological stewardship on private property. Landscape and Urban Planning 157: 586597.Google Scholar
Chandramohan, P., Kumar, S. J., Kumar, V. S., and Ilangovan, D. (1998). Fine particle deposition at Vainguinim tourist beach, Goa, India. Journal of Coastal Research 14: 10741081.Google Scholar
Chapman, D. M. (1989). Coastal Dunes of New South Wales: Status and Management. Sydney: University of Sydney Coastal Studies Unit Technical Report 89/3.Google Scholar
Chapman, M. G. and Underwood, A. J. (2011). Evaluation of ecological engineering of “armored” shorelines to improve their value as habitat. Journal of Experimental Marine Biology and Ecology 400: 302313.Google Scholar
Charbonneau, B. R., Wnek, J. P., Langley, J. A., Lee, G., and Balsamo, R. A. (2016). Above vs. belowground plant biomass along a barrier island: implications for dune stabilization. Journal of Environmental Management 182: 126133.Google Scholar
Charbonneau, B. R., Wootton, L. S., Wnek, J. P., Langley, J. A., and Posner, M. A. (2017). A species effect on storm erosion: invasive sedge stabilized dunes more than native grass during Hurricane Sandy. Journal of Applied Ecology 54: 13851394.Google Scholar
Charbonneau, B. R., Cochran, C., and Avenarius, C. (2019). What we know and what we think we know: revealing misconceptions about coastal management for sandy beaches along the U.S. Atlantic Seaboard. Journal of Environmental Management 245: 131142.Google Scholar
Cheney, D., Oestman, R., Volkhardt, G., and Getz, J. (1994). Creation of rocky intertidal and shallow subtidal habitats to mitigate for the construction of a large marina in Puget Sound, Washington. Bulletin of Marine Science 55: 772782.Google Scholar
Chittora, A., Joshi, V. B., and Kumar, M. P. (2017). Assessment of beach nourishment through analysis of beach profiles. International Journal of Civil Engineering and Technology 8: 153159.Google Scholar
Chiva, L., Pagán, J. I., López, I., Tenza-Abril, A. J., Aragonés, L., and Sánchez, I. (2018). The effects of sediment used in beach nourishment: study case El Portet de Moraira beach. Science of the Total Environment 628–629: 6473.Google Scholar
Choi, T.-J., Choi, J.-Y., Park, J.-Y., and Yang, Y.-J. (2020). Long-term temporal and spatial morphological variability of a nourished beach using the EOF analysis. Journal of Coastal Research SI95: 428432.Google Scholar
Choi, Y. D. (2007). Restoration ecology to the future: a call for new paradigm. Restoration Ecology 15: 351353.Google Scholar
Choi, Y. D. and Pavlovic, N. B. (1998). Experimental restoration of native vegetation in Indiana Dunes National Lakeshore. Restoration Ecology 6: 118129.Google Scholar
Christensen, S. N. and Johnsen, I. (2001). The lichen-rich coastal heath vegetation on the isle of Anholt, Denmark – conservation and management. Journal of Coastal Conservation 7: 1322.Google Scholar
Cialone, M. A. and Stauble, D. K. (1998). Historical findings on ebb shoal mining. Journal of Coastal Research 14: 537563.Google Scholar
Cipriani, L. E., Dreoni, A. M., and Pranzini, E. (1992). Nearshore morphological and sedimentological evolution induced by beach restoration: a case study. Bolletino di Oceanologia Teorica ed Applicata 10: 279295.Google Scholar
Clarke, M. L. and Rendell, H. M. (2015). “This restless enemy of all fertility”: exploring paradigms of coastal dune management in Western Europe over the last 700 years. Transactions of the Institute of British Geographers 40: 414429.Google Scholar
Clausner, J. E., Gebert, J. A., Rambo, A. T., and Watson, K. D. (1991). Sand bypassing at Indian River Inlet, Delaware. In Coastal Sediments 91. New York: American Society of Civil Engineers, pp. 11771191.Google Scholar
Clewell, A. and Rieger, J. P. (1997). What practitioners need from restoration ecologists. Restoration Ecology 5: 350354.Google Scholar
Coastal Engineering Research Center (CERC). (1984). Shore Protection Manual. Ft. Belvoir, VA: U.S. Army Corps of Engineers.Google Scholar
Colantoni, P., Menucci, D., and Nesci, O. (2004). Coastal processes and cliff recession between Gabicce and Pesaro (northern Adriatic Sea): a case history. Geomorphology 62: 257268.Google Scholar
Colenbrander, D. and Bavinck, M. (2017). Exploring the role of bureaucracy in the production of coastal risks, City of Capetown, South Africa. Ocean & Coastal Management 150: 3550.Google Scholar
Colombini, I. and Chelazzi, L. (2003). Influence of marine allochthonous input on sandy beach communities. Oceanography and Marine Biology: An Annual Review 41: 115159.Google Scholar
Coltorti, M. (1997). Human impact in the Holocene fluvial and coastal evolution of the Marche region, Central Italy. Catena 30: 311335.Google Scholar
Conaway, C. A. and Wells, J. T. (2005). Aeolian dynamics along scraped shorelines, Bogue Banks, North Carolina. Journal of Coastal Research 21: 242254.Google Scholar
Conger, T. and Chang, S. E. (2019). Developing indicators to identify coastal green infrastructure potential: the case of the Salish Sea region. Ocean & Coastal Management 175: 5369.Google Scholar
Conlin, M., Cohn, N., and Ruggiero, P. (2018). A quantitative comparison of low-cost structure from motion (SfM) data collection platforms on beaches and dunes. Journal of Coastal Research 34: 13411357.Google Scholar
Connors, P. G., Myers, J. P., Connors, C. S. W., and Pitelka, F. A. (1981). Interhabitat movements by sanderlings in relation to foraging profitability and the tidal cycle. Auk 98: 4964.Google Scholar
Conway, T. M. and Nordstrom, K. F. (2003). Characteristics of topography and vegetation at boundaries between the beach and dune on residential shorefront lots in two municipalities in New Jersey, USA. Ocean & Coastal Management 46: 635648.Google Scholar
Cooke, B. C., Jones, A. R., Goodwin, I. D., and Bishop, M. J. (2012). Nourishment practices on Australian sandy beaches: a review. Journal of Environmental Management 113: 319327.Google Scholar
Cooper, J. A. G. and Lemckert, C. (2012). Extreme sea-level rise and adaptation options for coastal resort cities: a qualitative assessment from the Gold Coast, Australia. Ocean & Coastal Management 64: 114.Google Scholar
Cooper, J. A. G. and McKenna, J. (2008). Working with natural processes: the challenge for coastal protection strategies. The Geographical Journal 174: 315331.Google Scholar
Cooper, J. A. G. and Pile, J. (2014). The adaptation-resistance spectrum: a classification of contemporary adaptation approaches to climate-related coastal change. Ocean & Coastal Management 94: 9098.Google Scholar
Cooper, J. A. G. and Pilkey, O. H. (2004). Alternatives to mathematical modeling of beaches. Journal of Coastal Research 20: 641644.Google Scholar
Cooper, N. J. and Pethick, J. S. (2005). Sediment budget approach to addressing coastal erosion problems in St. Ouen’s Bay, Jersey, Channel Islands. Journal of Coastal Research 21: 112122.Google Scholar
Cooper, N., Benson, N., McNeill, A., and Siddle, R. (2017). Changing coastlines in NE England: a legacy of colliery spoil tipping and the effects of its cessation. Proceedings of the Yorkshire Geological Society 61: 217229.Google Scholar
Cooper, W. S. (1958). The coastal sand dunes of Oregon and Washington. Geological Society of America Memoir 72.Google Scholar
Corbella, S. and Stretch, D. D. (2012). Geotextile sand filled containers as coastal defence: South African experience. Geotextiles and Geomembranes 35: 120130.Google Scholar
Corbin, J. D. and D’Antonio, C. M. (2012). Gone but not forgotten: invasive plant’s legacies on community and ecosystem properties. Invasive Plant Science and Management 5: 117124.Google Scholar
Cordshagen, H. (1964). Der Küstenschutz in Mecklenburg. Schwerin: Petermänken-Verlag.Google Scholar
Corlett, R. T. (2016). Restoration, reintroduction, and rewilding in a changing world. Trends in Ecology and Evolution 31: 453462.Google Scholar
Correll, D. L. (1991). Human impact on the functioning of landscape boundaries. In Holland, M. M., Naiman, R. J., and Risser, P. G. (Eds.), Ecotones: The Role of Landscape Boundaries in the Management and Restoration of Changing Environments. New York: Chapman and Hall, pp. 90109.Google Scholar
Costas, S., Ferreira, O., and Martinez, G. (2015). Why we decide to live with risk at the coast. Ocean & Coastal Management 118: 111.Google Scholar
Council of Europe. (1999). European Code of Conduct for Coastal Zones. CO-DBP(99)11. Strasbourg: Council of Europe.Google Scholar
Cowell, P. J., Thom, B. G., Jones, R. A., Everts, C. H., and Simanovic, D. (2006). Management of uncertainty in predicting climate-change impacts on beaches. Journal of Coastal Research 22: 232245.Google Scholar
Cox, D. (1997). On the value of natural relations. Environmental Ethics 19: 173183.Google Scholar
Crain, A. D., Bolten, A. B., and Bjorndal, K. A. (1995). Effects of beach nourishment on sea turtles: review and research initiatives. Restoration Ecology 3: 95104.Google Scholar
Cranz, G. and Boland, M. (2004). Defining the sustainable park: a fifth model for urban parks. Landscape Journal 23: 102120.Google Scholar
Crawford, K. M., Busch, M. H., Locke, H., and Luecke, N. C. (2020). Native soil microbial amendments generate trade-offs in plant productivity, diversity, and soil stability in coastal dune restorations. Restoration Ecology 28: 328336.Google Scholar
Creer, J., Litt, E., Ratcliffe, J., Rees, S., Thomas, N., and Smith, P. (2020). A comment on some of the conclusions made by Delgado-Fernandez et al. (2019). “Is ‘re-mobilisation’ nature conservation or nature destruction: a commentary”. Journal of Coastal Conservation 24: 29.Google Scholar
Cristiano, S. C., Portz, L., Nasser, P. C., Pinto, A. C., da Silva, P. R., and Barboza, E. G. (2018). Strategies for the management of the marine shoreline in the Orla Araranguá project (Santa Catarina, Brazil). In Botero, C. M., Cervantes, O., and Finkl, C. W. (Eds.), Beach Management Tools – Concepts, Methodologies and Case Studies. Cham, Switzerland: Springer International Publishing, pp. 735754.Google Scholar
Crowe, S. E., Bergquist, D. C., Sanger, D. M., and van Dolah, R. F. (2016). Physical and biological alterations following dredging in two beach nourishment borrow areas in South Carolina’s coastal zone. Journal of Coastal Research 32: 875889.Google Scholar
Cruz, H. da. (1996). Tourism and environment in the Mediterranean. In Salman, A. H. P. M., Langeveld, M. J., and Bonazountas, M. (Eds.), Coastal Management and Habitat Conservation, vol. II. Leiden: European Union for Coastal Conservation, pp. 113116.Google Scholar
Cullen, P. and Bird, E. C. F. (1980). The Management of Coastal Sand Dunes in South Australia. Black Rock, VIC: Geostudies.Google Scholar
Cunniff, S. E. (1985). Impacts of severe storms on beach vegetation. In Coastal Zone 85. New York: American Society of Civil Engineers, pp. 10221037.Google Scholar
Cunningham, D. J. and Wilson, S. P. (2003). Marine debris on beaches of the greater Sydney region. Journal of Coastal Research 19: 421430.Google Scholar
Currin, C. A., Chappell, W. S., and Deaton, A. (2010). Developing alternative shoreline armoring strategies: the living shoreline approach in North Carolina. In: Shipman, H., Dethier, M. N., Gelfenbaum, G., Fresh, K. L., and Dinicola, R. S. (Eds.), Puget Sound Shorelines and the Impacts of Armoring: Proceedings of a State of the Science Workshop, May 2009. U.S. Geological Survey Scientific Investigations Report 2010-5254, pp. 91–102.Google Scholar
Cutter, G. R., Diaz, R. J., Musick, J. A., et al. (2000). Environmental Survey of Potential Sand Resource Sites Offshore Delaware and Maryland. U.S. Department of the Interior, Minerals Management Service, OCS Study 2000-055.Google Scholar
Cutter, S., Nordstrom, K. F., and Kucma, G. (1979). Social and environmental factors influencing beach site selection. In Resource Allocation Issues in the Coastal Environment. Arlington, VA: The Coastal Society.Google Scholar
d’Angremond, K., van den Berg, E. J. F., and de Jager, J. H. (1992). Use and behavior of gabions in coastal protection. In Proceedings of the Twenty-Third Coastal Engineering Conference. New York: American Society of Civil Engineers, pp. 17481757.Google Scholar
Dahl, B. E. and Woodard, D. W. (1977). Construction of Texas coastal foredunes with sea oats (Uniolo paniculata) and bitter panicum (Panicum amarum). International Journal of Biometeorology 21: 267275.Google Scholar
Dally, W. R. and Osiecki, D. A. (2018). Evaluating the impact of beach nourishment on surfing: Surf City, Long Beach Island, New Jersey, USA. Journal of Coastal Research 34: 793805.Google Scholar
Daly, H. (2020). A note in defense of the concept of natural capital. Ecosystem Services 41: 101051.Google Scholar
Damgaard, C., Thomsen, M. P., Borchsenius, F., Nielsen, K. E., and Strandberg, M. (2013). The effect of grazing on biodiversity in coastal dune heathlands. Journal of Coastal Conservation 17: 663670.Google Scholar
Darke, I. B., Eamer, J. B. R., Beaugrand, H. E. R., and Walker, I. J. (2013). Monitoring considerations for a dynamic dune restoration project: Pacific Rim National Park Reserve, British Columbia, Canada. Earth Surface Processes and Landforms 38: 983993.Google Scholar
Darke, I. B., Walker, I. J., and Hesp, P. A. (2016). Beach-dune sediment budgets and dune morphodynamics following coastal dune restoration, Wickkaninnish Dunes, Canada. Earth Surface Processes and Landforms 41: 13701385.Google Scholar
Davenport, J. and Davenport, J. L. (2006). The impact of tourism and personal leisure transport on coastal environments: a review. Estuarine, Coastal and Shelf Science 67: 280292.Google Scholar
Davidson, A. T., Nicholls, J., and Leatherman, S. P. (1992). Beach nourishment as a coastal management tool: an annotated bibliography on developments associated with the artificial nourishment of beaches. Journal of Coastal Research 8: 9841022.Google Scholar
Davies, P., Curr, R., Williams, A. T., Hallégouët, B., Bodéré, J. C., and Koh, A. (1995). Dune management strategies: a semi-quantitative assessment of the interrelationships between coastal dune vulnerability and protection measures. In Salman, A. H. P. M., Berends, H., and Bonazountas, M. (Eds.), Coastal Management and Habitat Conservation. Leiden: EUCC, pp. 313331.Google Scholar
Davis, J. H. (1975). Stabilization of Beaches and Dunes by Vegetation in Florida. Florida Sea Grant-7. Gainesville: Florida Sea Grant College Program.Google Scholar
Davis, J. L., Currin, C., O’Brien, C., Raffenburg, C., and Davis, A. (2015). Living shorelines: coastal resilience with a blue carbon benefit. PLoS ONE 10(11): 118.Google Scholar
Davis, R. A. (1991). Performance of a beach nourishment project based on detailed multi-year monitoring: Redington Beach, FL. In Coastal Sediments 91. New York: American Society of Civil Engineers, pp. 21012115.Google Scholar
Davis, R. A. Jr., FitzGerald, M. V., and Terry, J. (1999). Turtle nesting on adjacent nourished beaches with different construction styles: Pinellas County, Florida. Journal of Coastal Research 15: 111120.Google Scholar
Dawson, R. J., Dickson, M. E., Nicholls, R. J., et al. (2009). Integrating analysis of risks of coastal flooding and cliff erosion under scenarios of long term change. Climatic Change 95: 249288.Google Scholar
De Bonte, A. J., Boosten, A., van der Hagen, H. G. J. M., and Sýkora, K. V. (1999). Vegetation development influenced by grazing in the coastal dunes near The Hague, The Netherlands. Journal of Coastal Conservation 5: 5968.Google Scholar
De Jong, B., Keijsers, J. G. S., Riksen, M. J. P. M., Krol, J., and Slim, P. A. (2014). Soft engineering vs. A dynamic approach in coastal dune management: a case study on the North Sea barrier island of Ameland, The Netherlands. Journal of Coastal Research 30: 670684.Google Scholar
de la Vega-Leinert, C., Stoll-Kleemann, S., and Wegener, E. (2018). Managed realignment (MR) along the eastern German Baltic Sea: a catalyst for conflict or for a coastal zone management consensus. Journal of Coastal Research 34: 586601.Google Scholar
De Lillis, M., Costanzo, L., Bianco, P. M., and Tinelli, A. (2004). Sustainability of sand dune restoration along the coast of the Tyrrhenian Sea. Journal of Coastal Conservation 10: 93100.Google Scholar
De Raeve, F. (1989). Sand dune vegetation and management dynamics. In van der Meulen, F., Jungerius, P. D., and Visser, J. H. (Eds.), Perspectives in Coastal Dune Management. The Hague: SPB Academic Publishing, pp. 99109.Google Scholar
de Ruig, J. H. M. (1996). Seaward coastal defence: limitations and possibilities. In Salman, A. H. P. M., Langeveld, M. J., and Bonazountas, M. (Eds.), Coastal Management and Habitat Conservation. Leiden: EUCC, pp. 453464.Google Scholar
de Ruig, J. H. M. and Hillen, R. (1997). Developments in Dutch coastline management: conclusions from the second governmental coastal report. Journal of Coastal Conservation 3: 203210.Google Scholar
De Ruyck, A. M. C., Ampe, C., and Langohr, R. (2001). Management of the Belgian coast: opinions and solutions. Journal of Coastal Conservation 7: 129144.Google Scholar
de Schipper, M. A., de Vries, S., Ruessink, G., et al. (2016). Initial spreading of a mega feeder nourishment: observations of the Sand Engine pilot project. Coastal Engineering 111: 2338.Google Scholar
De Vincenzo, A., Covelli, C., Molino, A. J., Pannone, M., Ciccaglione, M., and Molino, B. (2019). Long-term management policies of reservoirs: possible re-use of dredged sediments for coastal nourishment. Water 11: 15.Google Scholar
Dean, R. G. (1997). Models for barrier island restoration. Journal of Coastal Research 13: 694703.Google Scholar
Dean, R. G. (2002). Beach Nourishment: Theory and Practice. World Scientific Publishing Company.Google Scholar
Dech, J. P. and Maun, M. A. (2005). Zonation of vegetation along a burial gradient on the leeward slopes of Lake Huron. Canadian Journal of Botany 83: 227236.Google Scholar
Defeo, O. and McLachlan, A. (2005). Patterns, processes and regulatory mechanisms in sandy beach macrofauna: a multi-scale analysis. Marine Ecology Progress Series 295: 120.CrossRefGoogle Scholar
Defeo, O., McLachlan, A., Schoeman, D. S., et al. (2009). Threats to sandy beach ecosystems: a review. Estuarine, Coastal and Shelf Science 81: 112.Google Scholar
Deguchi, I., Ono, M., Araki, S., and Sawaragi, T. (1998). Motions of pebbles on pebble beach. In Coastal Engineering. Reston, VA: American Society of Civil Engineers, pp. 26542667.Google Scholar
Del Vecchio, S., Marba, N., Acosta, A., Vignolo, C., and Traveset, A. (2013). Effects of Posidonia oceanica beach-cast on germination, growth and nutrient uptake of coastal dune plants. PLoS ONE 8: e70607.Google Scholar
Del Vecchio, S., Jucker, T., Carboni, M., and Acosta, A. T. R. (2017). Linking plant communities on land and at sea: the effects of Posidonia oceanica wrack on the structure of dune vegetation. Estuarine, Coastal and Shelf Science 184: 3036.Google Scholar
Delgado-Fernandez, I., Davidson-Arnott, R. G. D., and Hesp, P. A. (2019). Is “re-mobilisation” nature restoration or nature destruction? A commentary. Journal of Coastal Conservation 23: 10931103.Google Scholar
Demirayak, F. and Ulas, E. (1996). Mass tourism in Turkey and its impact on the Mediterranean coast. In Salman, A. H. P. M., Langeveld, M. J., and Bonazountas, M. (Eds.), Coastal Management and Habitat Conservation, vol. II. Leiden: European Union for Coastal Conservation, pp. 117123.Google Scholar
Denevan, W. M. (1992). The pristine myth: the landscape of the Americas in 1492. Annals of the Association of American Geographers 82: 369385.Google Scholar
Des Roches, C. T. (2020). The preservation paradox and natural capital. Ecosystem Services 41: 101058.CrossRefGoogle Scholar
Dette, H.-H., Führböter, A., and Raudkivi, A. J. (1994). Interdependence of beach fill volumes and repetition intervals. Journal of Waterway, Port, Coastal, and Ocean Engineering 120: 580593.Google Scholar
Diaz, H. (1980). The mole crab Emerita talpoida (say); a case study of changing life history pattern. Ecological Monographs 50: 437456.Google Scholar
Diaz, R. J., Cutter, G. R., Jr., and Hobbs, C. H. (2004). Potential impacts of sand mining offshore of Maryland and Delaware: Part 2 – biological considerations. Journal of Coastal Research 20: 6169.CrossRefGoogle Scholar
Dickerson, D. D., Smith, J., Wolters, M., Theriot, C., Reine, K. J., and Dolan, J. (2007). A review of beach nourishment impacts on marine turtles. Shore and Beach 75(1): 4956.Google Scholar
Dlamini, L. Z. D. and Xulu, S. (2019). Monitoring mining disturbance and restoration over RBM site in South Africa using LandTrendr algorithm and landsat data. Sustainability 11: 6916.Google Scholar
Dodkin, M. and McDonald, T. (2019). Witnessing four decades of change in coastal park management: interview with Mike Dodkin. Ecological Management and Restoration 20: 192201.Google Scholar
Doing, H. (1985). Coastal foredune zonation and succession in various parts of the world. Vegetatio 61: 6575.Google Scholar
Donnelly, C., Kraus, N., and Larson, M. (2006). State of knowledge on measurement and modeling of coastal overwash. Journal of Coastal Research 22: 965991.Google Scholar
Donohue, K. A., Bocamazo, L. M., and Dvorak, D. (2004). Experience with groin notching along the northern New Jersey coast. Journal of Coastal Research SI33: 198214.Google Scholar
Doody, J. P. (1989). Management for nature conservation. Proceedings of the Royal Society of Edinburgh 96B: 247265.Google Scholar
Doody, J. P. (1995). Infrastructure development and other human influences on the coastline of Europe. In Salman, A. H. P. M., Berends, H., and Bonazountas, M. (Eds.), Coastal Management and Habitat Conservation. Leiden: EUCC, pp. 133151.Google Scholar
Doody, J. P. (2001). Coastal Conservation and Management: An Ecological Perspective. Dordrecht: Kluwer Academic Publishers.Google Scholar
Dornbusch, U. (2017). Design requirements for mixed sand and gravel beach defences under scenarios of sea level rise. Coastal Engineering 124: 1224.Google Scholar
Dornbusch, U., Williams, R. B. G., Moses, C., and Robinson, D. A. (2002). Life expectancy of shingle beaches: measuring in situ abrasion. Journal of Coastal Research SI36: 249255.CrossRefGoogle Scholar
Drius, M., Malavasi, M., Acosta, A. T. R., Ricotta, C., and Carranza, M. L. (2013). Boundary-based analysis for the assessment of coastal dune landscape integrity over time. Applied Geography 45: 4148.Google Scholar
Drucker, B. S., Waskes, W., and Byrnes, M. R. (2004). The US Minerals Management Service Outer Continental Shelf Sand and Gravel Program: environmental studies to assess the potential effects of offshore dredging operations in federal waters. Journal of Coastal Research 20: 15.Google Scholar
Dugan, J. E. and Hubbard, D. M. (2010). Loss of coastal strand habitat in southern California: the role of beach grooming. Estuaries and Coasts 33: 6777.Google Scholar
Dugan, J. E., Hubbard, D. M., McCrary, M. D., and Pierson, M. O. (2003). The response of macrofauna communities and shorebirds to macrophyte wrack subsidies on exposed sandy beaches of southern California. Estuarine, Coastal and Shelf Science 58S: 2540.Google Scholar
Dugan, J. E., Hubbard, D. M., Rodil, I. F., Revell, D. L., and Schroeter, S. (2008). Ecological effects of coastal armoring on sandy beaches. Marine Ecology 29(Suppl. 1): 160170.Google Scholar
Dugan, J. E., Airoldi, L., Chapman, M. G., Walker, S. J., and Schlacher, T. (2011). Estuarine and coastal structures: environmental effects, a focus on shore and nearshore structures. Treatise on Estuarine and Coastal Science 8: 1741.Google Scholar
Dugan, J. E., Emery, K. A., Alber, M., et al. (2018). Generalizing ecological effects of shoreline armoring across soft sediment environments. Estuaries and Coasts 41: S180S196.Google Scholar
Duncan, W. H. and Duncan, M. B. (1987). Seaside Plants of the Gulf and Atlantic Coasts. Washington, DC: Smithsonian Institution Press.Google Scholar
Dzhaoshvili, Sh. V. and Papashvili, I. G. (1993). Development and modern dynamics of alluvial-accumulative coasts of the eastern Black Sea. In Kos’yan, R. (Ed.), Coastlines of the Black Sea. New York: American Society of Civil Engineers, pp. 224233.Google Scholar
Eastwood, D. A. and Carter, R. W. G. (1981). The Irish dune consumer. Journal of Leisure Research 13: 273281.Google Scholar
Edge, B. L., Dowd, M., Dean, R. G., and Johnson, P. (1994). The reconstruction of Folly Beach. In Coastal Engineering: Proceedings of the Twenty-Fourth Coastal Engineering Conference. New York: American Society of Civil Engineers, pp. 34913506.Google Scholar
Ehrenfeld, J. G. (1990). Dynamics and processes of barrier island vegetation. Aquatic Science 2: 437480.Google Scholar
Ehrenfeld, J. G. (2000). Evaluating wetlands within an urban context. Ecological Engineering 15: 253265.Google Scholar
Eitner, V. (1996). The effect of sedimentary texture on beach fill longevity. Journal of Coastal Research 12: 447461.Google Scholar
Ellis, J. T. and Román-Rivera, M. A. (2019). Assessing natural and mechanical dune performance in a post-hurricane environment. Journal of Marine Science and Engineering 7(126): 115.Google Scholar
Ellison, J. C. (2018). Pacific island beaches: values, threats and rehabilitation. In Botero, C. M., Cervantes, O., and Finkl, C. W. (Eds.), Beach Management Tools – Concepts, Methodologies and Case Studies. Cham, Switzerland: Springer International Publishing, pp. 679700.Google Scholar
Emery, S. M. and Rudgers, J. A. (2010). Ecological assessment of dune restorations in the Great Lakes region. Restoration Ecology 18(S1): 184194.Google Scholar
Environmental Protection Agency. (1995). Rehabilitation and Revegetation: Best Practice. Environmental Management in Mining. Canberra: Australian Federal Environment Department.Google Scholar
Erwin, R. M., Truitt, B. R., and Jiménez, J. E. (2001). Ground-nesting waterbirds and mammalian carnivores in the Virginia barrier island region: running out of options. Journal of Coastal Research 17: 292296.Google Scholar
Escofet, A. and Espejel, I. (1999). Conservation and management-oriented ecological research in the coastal zone of Baja California, Mexico. Journal of Coastal Conservation 21: 4350.Google Scholar
Escudero, M., Silva, R., and Mendoza, E. (2014). Beach erosion driven by natural and human activity at Isla del Carmen barrier island, Mexico. Journal of Coastal Research SI71: 6274.Google Scholar
Espejel, I. (1993). Conservation and management of dry coastal vegetation. In Fermán-Almada, J. L., Gómez-Morin, L., and Fischer, D. W. (Eds.), Coastal Zone Management in Mexico: The Baja California Experience. New York: American Society of Civil Engineers, pp. 119136.Google Scholar
Espejel, J., Ahumada, B., Cruz, Y., and Heredia, A. (2004). Coastal vegetation as indicators for conservation. In Martínez, M. L. and Psuty, N. P. (Eds.), Coastal Dunes, Ecology and Conservation. Berlin: Springer-Verlag, pp. 297318.Google Scholar
Esteves, L. S. and Thomas, K. (2014). Managed realignment in practice in the UK: results from two independent surveys. . Journal of Coastal Research SI70: 407413.Google Scholar
European Commission. (2004). Living with Coastal Erosion in Europe – Sediment and Space for Sustainability. Luxemburg: Office for Official Publications of the European Commission.Google Scholar
Evans, A. J., Firth, L. B., Hawkins, S. J., Morris, E. S., Goudge, H., and Moore, P. J. (2016). Drill-cored rock pools: an effective method of ecological enhancement on artificial structures. Marine and Freshwater Research 67: 123130.Google Scholar
Everard, M., Jones, L., and Watts, B. (2010). Have we neglected the societal importance of sand dunes? An ecosystem services perspective. Aquatic Conservation: Marine and Freshwater Ecosystems 20: 476487.Google Scholar
Everts, C. H., Eldon, C. D., and Moore, J. (2002). Performance of cobble berms in southern California. Shore and Beach 70(4): 514.Google Scholar
Ewel, J. J. (1990). Restoration is the ultimate test of ecological theory. In Jordan, W. R. (Ed.), Restoration Ecology – A Synthetic Approach to Ecological Research. Cambridge: Cambridge University Press, p. 31.Google Scholar
Fairweather, P. G. and Henry, R. J. (2003). To clean or not to clean? Ecologically sensitive management of wrack deposits on sandy beaches. Ecological Management and Restoration 4: 227228.Google Scholar
Falk, D. A. (1990). Discovering the future, creating the past: some reflections on restoration. Restoration and Management Notes 8: 71.Google Scholar
Fang, J., Lincke, D., Brown, S., et al. (2020). Coastal flood risks in China through the 21st century – an application of DIVA. Science of the Total Environment 704: 135311.Google Scholar
Fanini, L., Marchetti, G. M., Scapini, F., and Defeo, O. (2007). Abundance and orientation responses of the sandhopper Talitrus saltator to beach nourishment and groynes building at San Rossore Regional Park, Tuscany, Italy. Marine Biology 152: 11691179.Google Scholar
Feagan, R. and Ripmeester, M. (2001). Reading private green space: competing geographical identities at the level of the lawn. Philosophy and Geography 4: 7995.Google Scholar
Feagin, R. A. (2005). Artificial dunes created to protect property on Galveston Island, Texas: the lessons learned. Ecological Restoration 23: 8994.Google Scholar
Feagin, R. (2013). Foredune restoration before and after hurricanes: inevitable destruction, certain reconstruction. In: Martínez, M. L., Gallego-Fernández, J. B., and Hesp, P. A. (Eds.), Restoration of Coastal Dunes. New York: Springer, pp. 93103.Google Scholar
Feagin, R., Figlus, J., Zinnert, J. C., et al. (2015). Going with the flow or against the grain? The promise of vegetation for protecting beaches, dunes, and barrier islands from erosion. Frontiers in Ecology and Environment 13: 203210.Google Scholar
Feagin, R. A., Furman, M., Salgado, K., et al. (2019). The role of beach and sand dune vegetation in mediating wave run up erosion. Estuarine, Coastal and Shelf Science 219: 97106.Google Scholar
Ferreira, J. C., Silva, C., Tenedório, J. A., Pontes, S., Encarnação, S., and Marques, L. (2006). Coastal greenways: interdisciplinarity and integration challenges for the management of developed coastal areas. Journal of Coastal Research SI39: 18331837.Google Scholar
Finkl, C. W. (2002). Long-term analysis of trends in shore protection based on papers appearing in the Journal of Coastal Research, 1984–2000. Journal of Coastal Research 18: 211224.Google Scholar
Firth, L. B., Thompson, R. C., Bohn, K., et al. (2014). Between a rock and a hard place: environmental and engineering considerations when designing coastal defence structures. Coastal Engineering 87: 122135.Google Scholar
Fischer, D. L. (1989). Response to coastal storm hazard: short-term recovery versus long-term planning. Ocean and Shoreline Management 12: 295308.Google Scholar
FitzGerald, D. M., van Heteren, S., and Montello, T. M. (1994). Shoreline processes and damage resulting from the Halloween Eve storm of 1991 along the north and south shores of Massachusetts Bay, USA. Journal of Coastal Research 10: 113132.Google Scholar
FitzGerald, D. M., Fenster, M. S., Argow, B. A., and Buynevich, I. V. (2008). Coastal impacts due to sea-level rise. Annual Review of Earth and Planetary Sciences 36: 601647.Google Scholar
FitzGerald, D. M., Georgiou, I., and Kulp, M. (2016). Restoration of the Chandeleur Barrier arc, Louisiana. Journal of Coastal Research SI75: 12821286.Google Scholar
Forman, R. T. T. (1995). Land Mosaics: The Ecology of Landscapes and Regions. Cambridge: Cambridge University Press.Google Scholar
Foster-Smith, J., Birchenough, A. C., Evans, S. M., and Prince, J. (2007). Human impacts on Cable Beach, Broome (Western Australia). Coastal Management 35: 181194.Google Scholar
Fouqueray, T., Trommetter, M., and Frascaria-Lacoste, N. (2018). Managed retreat of settlements and infrastructures: ecological restoration as an opportunity to overcome maladaptive coastal development in France. Restoration Ecology 26: 806812,Google Scholar
Freestone, A. L. and Nordstrom, K. F. (2001). Early evolution of restored dune plant microhabitats on a nourished beach at Ocean City, New Jersey. Journal of Coastal Conservation 7: 105116.Google Scholar
French, K. (2012). Competition strength of two significant invasive species in coastal dunes. Plant Ecology 213: 16671673.Google Scholar
French, P. W. (2006). Managed realignment – the developing story of a comparatively new approach to soft engineering. Estuarine, Coastal and Shelf Science 67: 409423.Google Scholar
Frihy, O. E., Deabes, E. A., and Helmy, E.-E. D. F. (2016). Compatibility analysis of dredged sediments from routine pathways and maintenance of harbor’s channels for reuse in nearshore nourishment in the Nile Delta, Egypt. Journal of Coastal Research 32: 555566.Google Scholar
Fuller, R. M. (1987). Vegetation establishment on shingle beaches. Journal of Ecology 75: 10771089.Google Scholar
Furmanczyk, K. (2013). Poland. In Pranzini, E. and Williams, A. (Eds.), Coastal Erosion and Protection in Europe. London: Routledge, pp. 8195.Google Scholar
Gallego-Fernández, J. B., Sánchez, I. A., and Ley, C. (2011). Restoration of isolated and small coastal sand dunes on the rocky coast of northern Spain. Ecological Engineering 37: 18221832.Google Scholar
Gallego-Fernández, J. B., Morales-Sánchez, J. A., Martínez, M. L., García-Franco, J. G., and Zunzunegui, M. (2020). Recovery of beach-foredune vegetation after disturbance by storms. Journal of Coastal Research SI95: 3438.Google Scholar
Gallien, T. W., O’Reilly, W. C., Flick, R. E., and Guza, R. T. (2015). Geometric properties of anthropogenic flood control berms on southern California beaches. Ocean & Coastal Management 105: 3547.Google Scholar
Gangaiya, P., Beardsmore, A., and Miskiewicz, T. (2017). Morphological changes following vegetation removal and foredune re-profiling at Woonona Beach, New South Wales, Australia. Ocean & Coastal Management 146: 1525.Google Scholar
Gann, G. D., McDonald, T., Walder, B., et al. (2019). International principles and standards for the practice of ecological restoration. Second edition. Restoration Ecology 27: S1S46.Google Scholar
Gao, J., Kennedy, D. M., and Konlechner, T. M. (2020). Coastal dune mobility over the past century: A global review. Progress in Physical Geography 44: 814–836.Google Scholar
Garbutt, R. A., Reading, C. J., Wolters, M., Gray, A. J., and Rothery, P. (2006). Monitoring the development of intertidal habitats on former agricultural land after the managed realignment of coastal defenses at Tollesbury, Essex, UK. Marine Pollution Bulletin 53: 155164.Google Scholar
Garcia-Lozano, C., Pintó, J., and Daunis-i-Estadella, P. (2018). Changes in coastal dune systems on the Catalan shoreline (Spain, NW Mediterranean Sea). Comparing dune landscapes between 1890 and 1960 with their current status. Estuarine, Coastal and Shelf Science 208: 235247.Google Scholar
Garcia-Lozano, C., Pintó, J., and Roig-Munar, F. X. (2020). Set of indices to assess dune development and dune restoration potential in beach-dune systems on Mediterranean developed coasts. Journal of Environmental Management 259: 109754.Google Scholar
García-Mora, M. R., Gallego-Fernández, J. B., and García-Novo, F. (2000). Plant diversity as a suitable tool for coastal dune vulnerability assessment. Journal of Coastal Research 16: 990995.Google Scholar
García Novo, F., Díaz Barradas, M. C., Zunzunegui, M., García Mora, R., and Gallego Fernández, J. B. (2004). Plant functional types in coastal dune habitats. In Martínez, M. L. and Psuty, N. P. (Eds.), Coastal Dunes, Ecology and Conservation. Berlin: Springer-Verlag, pp. 155169.Google Scholar
García-Romero, L., Delgado-Fernández, I., Hesp, P. A., Hernández-Calvento, L., Hernández-Cordero, A. I., and Viera-Pérez, M. (2019). Biogeomorphological processes in an arid transgressive dunefild as indicators of human impact by urbanization. Science of the Total Environment 650: 7386.Google Scholar
Garcin, M., Desmazes, F., Lerma, A. N., Gouguet, L., and Météreau, V. (2020). Contributions of lightweight revolving laser scanner, HiRes UAV LiDARS and photogrammetry for characterization of coastal aeolian morphologies. Journal of Coastal Research SI95: 10941100.Google Scholar
Gardner, E. and Burningham, H. (2013). Ecology and conservation of the rare annual Petrorhagia nanteuilii (Childing Pink) on the vegetated shingle spits of Pagham Harbour, West Sussex. Journal of Coastal Conservation 17: 589600.Google Scholar
Gares, P. A. (1989). Geographers and public policy making: lessons learned from the failure of the New Jersey Dune Management Plan. Professional Geographer 41: 2029.Google Scholar
Gares, P. A. and Nordstrom, K. F. (1995). A cyclic model of foredune blowout evolution for a leeward coast, Island Beach, New Jersey. Annals of the Association of American Geographers 85: 120.Google Scholar
Gauci, M. J., Deidun, A., and Schembri, P. J. (2005). Faunistic diversity of Maltese pocket sandy and shingle beaches: are these of conservation value? Oceanologia 47: 219241.Google Scholar
Gedan, K. B., Kirwan, M. L., Wolanski, E., Barbier, E. B., and Silliman, B. R. (2011). The present and future role of coastal wetland vegetation in protecting shorelines: answering recent challenges to the paradigm. Climatic Change 106: 729.Google Scholar
Geelen, L. H. W. T., Kamps, P. T. W. J., and Olsthoorn, T. N. (2017). From exploitation to sustainable use, an overview of 160 years of water extraction in the Amsterdam dunes, the Netherlands. Journal of Coastal Conservation 21: 657668.Google Scholar
Gemma, J. N. and Koske, R. E. (1997). Arbuscular mycorrhizae in sand dune plants of the North Atlantic coast of the U.S.: field and greenhouse studies. Journal of Environmental Management 50: 251264.Google Scholar
Gerhardt, P. (1900). Handbuch des Deutschen Dünenbaues. Berlin: Paul Parey.Google Scholar
Gerlach, A. (1992). Dune cliffs: a buffered system. In Carter, R. W. G., Curtis, T. G. F., and Sheehy-Skeffington, M. J. (Eds.), Coastal Dunes: Geomorphology, Ecology and Management for Conservation. Rotterdam: A.A. Balkema, pp. 5155.Google Scholar
Gesing, F. (2019). The politics of artificial dunes: sustainable coastal protection measures and contested socio-natural objects. Die Erde 150: 145157.Google Scholar
Ghate, S. D., Sridhar, K. R., and Karum, N. C. (2014). Macrofungi on the coastal sand dunes of south-western India. Mycosphere 5: 144151.Google Scholar
Gibeaut, J. C., Hepner, T. L., Waldinger, R., Andrews, J. R., Smyth, R. C., and Gutierrez, R. (2003). Geotubes for temporary erosion control and storm surge protection along the Gulf of Mexico shoreline of Texas. Proceedings of the 13th Biennial Coastal Zone Conference.Google Scholar
Gibson, D. J. and Looney, P. B. (1994). Vegetation colonization of dredge spoil on Perdido Key, Florida. Journal of Coastal Research 10: 133143.Google Scholar
Gibson, D. J., Ely, J. S., and Looney, P. B. (1997). A Markovian approach to modeling succession on a coastal barrier island following beach nourishment. Journal of Coastal Research 13: 831841.Google Scholar
Gilburn, A. S. (2012). Mechanical grooming and beach award status are associated with low strandline biodiversity in Scotland. Estuarine, Coastal and Shelf Science 107: 8188.Google Scholar
Gobster, P. H., Nassauer, J. I., Daniel, T. C., and Fry, T. (2007). The shared landscape: what does aesthetics have to do with ecology. Landscape Ecology 22: 959972.Google Scholar
Godfrey, P. J. (1977). Climate, plant response, and development of dunes on barrier beaches along the U.S. east coast. International Journal of Biometeorology 21: 203215.Google Scholar
Godfrey, P. J. and Godfrey, M. M. (1981). Ecological effects of off-road vehicles on Cape Cod. Oceanus 23: 5667.Google Scholar
Godfrey, P. J., Leatherman, S. P., and Zaremba, R. (1979). A geobotanical approach to classification of barrier beach systems. In Leatherman, S. P. (Ed.), Barrier Islands from the Gulf of St. Lawrence to the Gulf of Mexico. New York: Academic Press, pp. 99126.Google Scholar
Goeldner-Gianella, L. (2007). Perceptions and attitudes toward de-polderisation in Europe: a comparison of five opinion surveys in France and the UK. Journal of Coastal Research 23: 12181230.Google Scholar
Goeldner-Gianella, L., Bertrand, F., Oiry, A., and Grancher, D. (2015). Depolderization policy against coastal flooding on the French Atlantic coast: the case of Arachon Bay. Ocean & Coastal Management 116: 98107.Google Scholar
Goldin, M. R. and Regosin, J. V. (1998). Chick behavior, habitat use, and reproductive success of piping plovers at Goosewing Beach, Rhode Island. Journal of Field Ornithology 69: 228234.Google Scholar
Golfi, P. (1996). The future of tourism in the Mediterranean. In Salman, A. H. P. M., Langeveld, M. J., and Bonazountas, M. (Eds.), Coastal Management and Habitat Conservation, vol. II. Leiden: European Union for Coastal Conservation, pp. 133140.Google Scholar
Gómez-Pina, G. (2004). The importance of aesthetic aspects in the design of coastal groins. Journal of Coastal Research SI33: 8398.Google Scholar
Gómez-Pina, G., Muñoz-Pérez, J. J., Ramírez, J. L., and Ley, C. (2002). Sand dune management problems and techniques, Spain, Journal of Coastal Research SI36: 325332.Google Scholar
Gómez-Pina, G., Muñoz-Pérez, J. J., Fages, L., Ramírez, J. L., Enriques, J., and de Sobrino, J. (2004). A critical review of urban beach nourishment projects in Cadiz City after twelve years. In Coastal Engineering 2004: Proceedings of the 29th International Conference. New York: American Society of Civil Engineers, pp. 34543466.Google Scholar
Gonçalves, D. S., Pinheiro, L. M., Silva, P. A., et al. (2014). Morphodynamic evolution of a sand extraction excavation offshore Vale do Lobo, Algarve, Portugal. Coastal Engineering 88: 7587.Google Scholar
Gopalakrishnan, S., Landry, C. E., Smith, M. D., and Whitehead, J. C. (2016). Economics of coastal erosion and adaptation to sea level rise. Annual Review of Resource Economics 8: 119139.Google Scholar
Gore, S. (2007). Framework development for beach management in the British Virgin Islands. Ocean & Coastal Management 50: 732753.Google Scholar
Gorzelany, J. F. and Nelson, W. G. (1987). The effects of beach nourishment on the benthos of a subtropical Florida beach. Marine Environmental Research 21: 7594.Google Scholar
Gosz, J. R. (1991). Fundamental ecological characteristics if landscape boundaries. In Holland, M. M., Naiman, R. J., and Risser, P. G. (Eds.), Ecotones: The Role of Landscape Boundaries in the Management and Restoration of Changing Environments. New York: Chapman and Hall, pp. 830.Google Scholar
Graetz, K. E. (1973). Seacoast Plants of the Carolinas for Conservation and Beautification. UNC-SG-73-06. Raleigh: North Carolina University Sea Grant.Google Scholar
Grafals-Soto, R. (2012). Effects of sand fences on coastal dune vegetation distribution. Geomorphology 145–146: 4555.Google Scholar
Grafals-Soto, R. and Nordstrom, K. F. (2009). Sand fences in the coastal zone: intended and unintended effects. Environmental Management 44: 420429.Google Scholar
Granja, H. M. and Carvalho, G. S. (1995). Is the coastline “protection” of Portugal by hard engineering structures effective? Journal of Coastal Research 11: 12291241.Google Scholar
Greene, K. (2002). Beach Nourishment: A Review of the Biological and Physical Impacts. Washington, DC: Atlantic States Marine Fisheries Commission Habitat Management Series No. 7.Google Scholar
Gribbin, T. (1990). Sand dune rehabilitation and management in Prince Edward Island National Park. In Davidson-Arnott, R. G. D. (Ed.), Proceedings of the Symposium on Coastal Sand Dunes. Ottawa: National Research Council Canada, pp. 433446.Google Scholar
Griggs, G. and Patsch, K. (2019). The protection/hardening of California’s coast: times are changing. Journal of Coastal Research 35: 10511061.Google Scholar
Grime, J. P. (1979). Plant Strategies and Vegetation Processes. London: John Wiley & Sons.Google Scholar
Grootjans, A. P., Geelan, H. W. T., Jansen, A. J. M., and Lammerts, E. J. (2002). Restoration of coastal dune slacks in the Netherlands. Hydrobiologia 478: 181203.Google Scholar
Grootjans, A. P., Adema, E. B., Bekker, R. M., and Lammerts, E. J. (2004). Why young coastal dune slacks sustain a high biodiversity. In Martínez, M. L. and Psuty, N. P. (Eds.), Coastal Dunes, Ecology and Conservation. Berlin: Springer-Verlag, pp. 85101.Google Scholar
Grootjans, A. P., Dullo, B. S., Kooijman, A. M., Bekker, R. M., and Aggenbach, C. (2013). Restoration of dune vegetation in the Netherlands. In Martínez, M.L., Gallego-Fernández, J. B., and Hesp, P. A. (Eds.), Restoration of Coastal Dunes. Berlin: Springer, pp. 235253.Google Scholar
Grottoli, E., Bertoni, D., and Ciavola, P. (2017). Short- and medium-term response to storms on three Mediterranean coarse-grained beaches. Geomorphology 295: 738748.CrossRefGoogle Scholar
Grumbine, R. E. (1994). Wildness, wise use, and sustainable development. Environmental Ethics 16: 241249.Google Scholar
Gueben-Venière, S. (2016). How do civil engineers see the coast they manage? A comparative approach between The Netherlands, England and France. In Baptiste, A. (Ed.), Coastal Management: Changing Coast, Changing Climate, Changing Minds. International Coastal Management Conference. London: ICE Publishing, pp. 489500.Google Scholar
Guisado-Pintado, E., Jackson, D. W. T., and Rogers, D. (2019). 3D mapping efficacy of a drone and terrestrial laser scanner over a temperate beach-dune zone. Geomorphology 328: 157172.Google Scholar
Halle, S. (2007). Present state on future perspectives of restoration ecology – introduction. Restoration Ecology 15: 304306.Google Scholar
Hamer, D., Belcher, C., and Miller, C. (1992). Restoration of Sand Dunes along the Mid-Atlantic Coast. Somerset, NJ: U.S. Department of Agriculture Natural Resources Conservation Service.Google Scholar
Hamm, L., Capobianco, M., Dette, H. H., Lechuga, A., Spanhoff, R., and Stive, M. J. F. (2002). A summary of European experience with shore nourishment. Coastal Engineering 47: 237264.Google Scholar
Hanley, M. E., Hoggart, S. P. G., Simmonds, D. J., et al. (2014). Shifting sands? Coastal protection by sand banks, beaches and dunes. Coastal Engineering 87: 136146.Google Scholar
Hanley, N. and Roberts, M. (2019). The economic benefits of invasive species management. People and Nature 1: 124137.Google Scholar
Hanson, H., Brampton, A., Capobianco, M., et al. (2002). Beach nourishment projects, practices, and objectives – a European overview. Coastal Engineering 47: 81111.Google Scholar
Harley, M. D. and Ciavola, P. (2013). Managing local coastal inundation risk using real-time forcasts and artificial dune placements. Coastal Engineering 77: 7790.Google Scholar
Harman, B. P., Heyenga, S., Taylor, B. M., and Fletcher, C. S. (2015). Global lessons for adapting coastal communities to protect against storm surge inundation. Journal of Coastal Research 31: 790801.Google Scholar
Harris, L. D. and Scheck, J. (1991). From implications to applications: the dispersal corridor principal applied to the conservation of biological diversity. In Saunders, D. A. and Hobbs, R. J. (Eds.), Nature Conservation 2: The Role of Corridors. Chipping Norton, NSW: Surrey Beatty and Sons, pp. 189220.Google Scholar
Harris, L., Nel, R., Smale, M., and Schoeman, D. (2011). Swashed away? Storm impacts on sandy beach macrofaunal communities. Estuarine, Coastal and Shelf Science 94: 210221.Google Scholar
Harris, M. E. and Ellis, J. T. (2020). A holistic approach to evaluating dune cores. Journal of Coastal Conservation 24: 42.Google Scholar
Harris, T. B., Rajakaruna, N., Nelson, S. J., and Vaux, P. D. (2012). Stressors and threats to the flora of Acadia National Park, Maine: current knowledge, information gaps, and future directions. The Journal of the Torrey Botanical Society 139: 323344.Google Scholar
Hartley, B. L., Thompson, R. C., and Pahl, S. (2015). Marine litter education boosts children’s understanding and self-reported actions. Marine Pollution Bulletin 90: 209217.Google Scholar
Hatzikyriakou, A., Lin, N., Gong, J., Xian, S., Hu, X, and Kennedy, A. (2016). Component-based vulnerability analysis for residential structures subjected to storm surge impact from Hurricane Sandy. Natural Hazards Review 17: 05015005-1-15.Google Scholar
Hemmingsen, M. A., Eikaas, H. S., and Marsden, D. C. J. (2019). A GIS approach to sediment displacement in mixed sand and gravel beach environments. Journal of Environmental Management 249: 109083.Google Scholar
Henderson, S. P. B., Perkins, N. H., and Nelischer, M. (1998). Residential lawn alternatives: a study of their distribution, form and structure. Landscape and Urban Planning 42: 135145.Google Scholar
Hernández-Cordero, A. I., Hernández-Calvento, L., and Pérez-Chacon, E. (2017). Vegetation changes as an indicator of impact from tourist development in an arid transgressive coastal dune field. Land Use Policy 64: 479491.Google Scholar
Hertling, U. M. and Lubke, R. A. (1999). Use of Ammophila arenaria for dune stabilization in South Africa and its current distribution – perceptions and problems. Environmental Management 24: 467482.Google Scholar
Heslenfeld, P., Jungerius, P. D., and Klijn, J. A. (2004). European coastal dunes: ecological values, threats, opportunities and policy development. In Martínez, M. L. and Psuty, N. P. (Eds.), Coastal Dunes, Ecology and Conservation. Berlin: Springer-Verlag, pp. 335351.Google Scholar
Hesp, P. A. (1989). A review of biological and geomorphological processes involved in the initiation and development of incipient foredunes. Proceedings of the Royal Society of Edinburgh 96B: 181201.Google Scholar
Hesp, P. A. (1991). Ecological processes and plant adaptations on coastal dunes. Journal of Arid Environments 21: 165191.Google Scholar
Hesp, P. A. and Hilton, M. J. (2013). Restoration of foredunes and transgressive dunefields: case studies from New Zealand. In: Martínez, M. L., Gallego-Fernández, J. B., and Hesp, P. A. (Eds.), Restoration of Coastal Dunes. New York: Springer, pp. 6792.Google Scholar
Hickman, T. and Cocklin, C. (1992). Attitudes toward recreation and tourism development in the coastal zone: a New Zealand case study. Coastal Management 20: 269289.Google Scholar
Higgs, E. S. (1997). What is good ecological restoration? Conservation Biology 11: 338348.Google Scholar
Higgs, E. S. (2003). Nature by Design: People, Natural Process, and Ecological Restoration. Cambridge, MA: The MIT Press.Google Scholar
Higgs, E. S. (2006). Restoration goes wild: a reply to Throop and Purdom. Restoration Ecology 14: 500503.Google Scholar
Higgs, E., Harris, J., Murphy, S., et al. (2018). On principles and standards in ecological restoration. Restoration Ecology 26: 399403.Google Scholar
Hill-Spanik, K. M., Smith, A. S., and Plante, C. J. (2019). Recovery of benthic microalgal biomass and community structure following beach renourishment at Folly Beach, South Carolina. Estuaries and Coasts 42: 157172.Google Scholar
Hilton, M. J. (2006). The loss of New Zealand’s active dunes and the spread of marram grass (Ammophila arenaria). New Zealand Geographer 62: 105120.Google Scholar
Hilton, M., Duncan, M., and Jul, A. (2005). Processes of Ammophila arenaria (Marram grass) invasion and indigenous species displacement, Stewart Island, New Zealand. Journal of Coastal Research 21: 175185.Google Scholar
Hilton, M., Harvey, N., Hart, A., James, K., and Arbuckle, C. (2006). The impact of exotic dune grass species on foredune development in Australia and New Zealand: a case study of Ammophila arenaria and Thinopyrum junceiforme. Australian Geographer 37: 313334.Google Scholar
Hilton, M., Woodley, D., Sweeney, C., and Konlechner, T. (2009). The development of a prograded foredune barrier following Ammophila arenaria eradication, Doughboy Bay, Stewart Island. Journal of Coastal Research SI56: 317321.Google Scholar
Hilton, M., Konlechner, T., McLachlan, K., Lim, D., and Lord, J. (2019). Long-lived seed banks of Ammophila arenaria prolong dune restoration programs. Journal of Coastal Conservation 23: 461471.Google Scholar
Hirsch, S. E., Kedzuf, S., and Perrault, J. R. (2019). Impacts of a geotextile container dune core on marine turtle nesting in Juno Beach, Florida, United States. Restoration Ecology 27: 431439.Google Scholar
Hobbs, C. H. III (2002). An investigation of potential consequences of marine mining in shallow water: an example from the mid-Atlantic coast of the United States. Journal of Coastal Research 18: 94101.Google Scholar
Hobbs, R. J. and Norton, D. A. (1996). Towards a conceptual framework for restoration ecology. Restoration Ecology 4: 93110.Google Scholar
Hofstede, J. (2019). Küstenschutz in Schleswig-Holstein: ein Überblick über Strategien und Massnahmen. Die Küste 87.Google Scholar
Holcomb, B. (2016). A sure thing: tourism recovery in New York and New Jersey after Hurricane Sandy. In O’Neil, K. M. and van Abs, D. J. (Eds.), Taking Chances: The Coast after Hurricane Sandy. New Brunswick, NJ: Rutgers University Press, pp. 177189.Google Scholar
Holz, R., Hermann, C., and Müller-Motzfeld, G. (1996.) Vom Polder zum Ausdeichungsgebiet: Das Projekt Karrendorfer Wiesen und die Zukunft der Küstenüberflutungsgebiete in Mecklenburg-Vorpommern. Natur und Naturschutz in Mecklenburg-Vorpommern 32: 327.Google Scholar
Hoogeboom, K. R. (1989). Restoration and development guidelines for ocean beach recreation areas. In Coastal Zone 89. New York: American Society of Civil Engineers, pp. 31203134.Google Scholar
Hooke, J. M. and Bray, M. J. (1995). Coastal groups, littoral cells, policies and plans in the UK. Area 27: 358368.Google Scholar
Hoonhout, B. and de Vries, S. (2017). Aeolian sediment supply at a mega nourishment. Coastal Engineering 123: 1120.Google Scholar
Hoonhout, B. and de Vries, S. (2019). Simulating spatiotemporal aeolian sediment supply at a mega nourishment. Coastal Engineering 145: 2135.Google Scholar
Hooton, N., Miller, D. L., Thetford, M., and Claypool, B. S. (2014). Survival and growth of planted Uniola paniculata and dune building using surrogate wrack on Perdido Key Florida, U.S.A. Restoration Ecology 22: 701707.Google Scholar
Horn, D. P. and Walton, S. M. (2007). Spatial and temporal variations of sediment size on a mixed sand and gravel beach. Sedimentary Geology 202: 509528.Google Scholar
Hornsey, W. P., Carley, J. T., Coghlan, I. R., and Cox, R. J. (2011). Geotextile sand container shoreline protection systems: design and application. Geotextiles and Geomembranes 29: 425439.Google Scholar
Hose, T. A. (1998). Selling coastal geology to visitors. In Hooke, J. (Ed.), Coastal Defence and Earth Science Conservation. Bath: The Geological Society, pp. 178195.Google Scholar
Hotta, S., Kraus, N. C., and Horikawa, K. (1987). Function of sand fences in controlling wind-blown sand. In Coastal Sediments 87. New York: American Society of Civil Engineers, pp. 772787.Google Scholar
Hotta, S., Kraus, N. C., and Horikawa, K. (1991). Functioning of multi-row sand fences in forming foredunes. In Coastal Sediments 91. New York: American Society of Civil Engineers, pp. 261275.Google Scholar
Houser, C., Wernette, P., Rentschlar, E., Jones, H., Hammond, B., and Trimble, S. (2015). Post-storm beach and dune recovery: implications for barrier island resilience. Geomorphology 234: 5463.Google Scholar
Houston, J. R. (1996). Engineering practice for beach-fill designs. Shore and Beach 64(3): 2735.Google Scholar
Houston, J. R. (2013). The economic value of beaches – a 2013 update. Shore and Beach 81(1): 311.Google Scholar
Houston, J. R. (2017). Shoreline change in response to sea-level rise on Florida’s west coast. Journal of Coastal Research 336: 12431260.Google Scholar
Howe, M. A. (2015). Coastal soft cliff invertebrates are reliant upon dynamic coastal processes. Journal of Coastal Conservation 19: 809820.Google Scholar
Howe, M. A., Knight, G. T., and Clee, C. (2010). The importance of coastal sand dunes for terrestrial invertebrates in Wales and the UK, with particular reference to aculeate Hymenoptera (bees, wasps & ants). Journal of Coastal Conservation 14: 91102.CrossRefGoogle Scholar
Hu, X., Liu, B., Wu, Z. Y., and Gong, J. (2016). Analysis of dominant factors associated with hurricane damages to residential structures using the rough set theory. Natural Hazards Review 17: 04016005-1-10.Google Scholar
Hummel, P., Thomas, S., Dillon, J., Johannessen, J., Schlenger, P., and Laprade, W. T. (2005). Seahurst Park: restoring nearshore habitat and reconnecting natural sediment supply processes. In Puget Sound Georgia Basin Research Conference 2005. Puget Sound Action Team, F7, pp. 15.Google Scholar
Huxel, G. R. and Hastings, A. (1999). Habitat loss, fragmentation, and restoration. Restoration Ecology 7: 309315.Google Scholar
Ibrahim, J. C., Holmes, P., and Blanco, B. (2006). Response of a gravel beach to swash zone hydrodynamics. Journal of Coastal Research SI39: 16851690.Google Scholar
Innocenti, R. A., Feagin, R. A., and Huff, T. P. (2018). The role of Sargassum macroalgal wrack in reducing coastal erosion. Estuarine, Coastal and Shelf Science 214: 8288.Google Scholar
Irish, J., Lynett, P. J., Weiss, R., Smallegan, S. M., and Cheng, W. (2013). Buried relic seawall mitigates Hurricane Sandy’s impacts. Coastal Engineering 80: 7982.Google Scholar
Isermann, M. and Krisch, H. (1995). Dunes in contradiction with different interests. An example: the camping-ground prerow (Darss/Baltic Sea). In Salman, A. H. P. M., Berends, H., and Bonazountas, M. (Eds.), Coastal Management and Habitat Conservation. Leiden: EUCC, pp. 439449.Google Scholar
Itzkin, M., Moore, L. J., Ruggiero, P., and Hacker, S. D. (2020). The effect of sand fencing on the morphology of natural dune systems. Geomorphology 352: 106995.Google Scholar
Jackson, D. W. T., Costas, S., González-Villanueva, R., and Cooper, A. (2019). A global “greening” of coastal dunes: an integrated consequence of climate change? Global and Planetary Change 182: 103026.Google Scholar
Jackson, L. L., Lopukhine, N., and Hillyard, D. (1995). Ecological restoration: a definition and comments. Restoration Ecology 3: 7176.Google Scholar
Jackson, N. L. and Nordstrom, K. F. (2011). Aeolian transport and landforms in managed coastal systems: a review. Aeolian Research 3: 181196.Google Scholar
Jackson, N. L. and Nordstrom, K. F. (2020). Trends in research on beaches and dunes on sandy shores, 1969–2019. Geomorphology 366: 106737.Google Scholar
Jackson, N. L., Nordstrom, K. F., and Smith, D. R. (2002). Geomorphic-biotic interactions on beach foreshores in estuaries. Journal of Coastal Research SI36: 414424.Google Scholar
Jackson, N. L., Smith, D. R., Tiyarattanachi, R., and Nordstrom, K. F. (2007). Use of a small beach nourishment project to enhance habitat suitability for horseshoe crabs. Geomorphology 89: 172185.Google Scholar
Jackson, N. L., Smith, D. R., and Nordstrom, K. F. (2008). Physical and chemical changes in the foreshore of an estuarine beach: implications for viability and development of horseshoe crab (Limulus polyphemus) eggs. Marine Ecology Progress Series 355: 209218.Google Scholar
Jackson, N. L., Nordstrom, K. F., Saini, S., and Smith, D. R. (2010). Effects of nourishment on the form and function of an estuarine beach. Ecological Engineering 36: 17091718.Google Scholar
Jackson, N. L., Nordstrom, K. F., Feagin, R. A., and Smith, W. K. (2013). Coastal geomorphology and restoration. Geomorphology 199: 17.Google Scholar
Jackson, N. L., Saini, S., Smith, D. R., and Nordstrom, K. F. (2020). Egg exhumation and transport on a foreshore under wave and swash processes. Estuaries and Coasts 43: 286297.Google Scholar
Janssen, M. P. (1995). Coastal management: restoration of natural processes in foredunes. In Healy, M. G. and Doody, J. P. (Eds.), Directions in European Coastal Management. Cardigan: Samara Publishing Ltd., pp. 195198.Google Scholar
Janssen, M. P. J. M. and Salman, A. H. P. M. (1995). A national strategy for dune conservation in The Netherlands. In Salman, A. H. P. M., Berends, H., and Bonazountas, M. (Eds.), Coastal Management and Habitat Conservation. Leiden: EUCC, pp. 153159.Google Scholar
Jantarasami, L. C., Lawler, J. J., and Thomas, C. W. (2010). Institutional barriers to climate change adaptation in U.S. national parks and forests. Ecology and Society 15: 33.Google Scholar
Jaramillo, E., Contreras, H., and Bollinger, A. (2002). Beach and faunal response to the construction of a seawall in a sandy beach of south central Chile. Journal of Coastal Research 18: 523529.Google Scholar
Jayappa, K. S. and Deepika, B. (2018). Impacts of coastal erosion, anthropogenic activities and their management on tourism and coastal ecosystems: a study with reference to Karnataka coast, India. In Botero, C. M., Cervantes, O., and Finkl, C. W. (Eds.), Beach Management Tools – Concepts, Methodologies and Case Studies. Cham, Switzerland: Springer International Publishing, pp. 421440.Google Scholar
Jellinek, S., Wilson, K. A., Hagger, V., et al. (2019). Integrating diverse social and ecological motivations to achieve landscape restoration. Journal of Applied Ecology 56: 246252.Google Scholar
Jennings, R. and Shulmeister, J. (2002). A field based classification scheme for gravel beaches. Marine Geology 186: 211228.Google Scholar
Jentsch, A. (2007). The challenge to restore process in the face of nonlinear dynamics – on the crucial role of disturbance regimes. Restoration Ecology 15: 334339.Google Scholar
Jeschke, L. (1983). Landeskulturelle Probleme des Salzgraslandes an der Küste. Naturschutzarbeit in Mecklenburg 26: 512.Google Scholar
Johnson, D. E. and Dagg, S. (2003). Achieving public participation in coastal zone environmental impact assessment. Journal of Coastal Conservation 9: 1318.Google Scholar
Johnson, L. and Bauer, W. (1987). Beach stabilization design. In Coastal Zone 87. New York: American Society of Civil Engineers, pp. 14321445.Google Scholar
Johnstone, C. A., Pastor, J., and Pinay, G. (1992). Quantitative methods for studying landscape boundaries. In Hansen, A. J. and di Castri, F. (Eds.), Landscape Boundaries: Consequences for Biotic Diversity and Ecological Flows. New York: Springer-Verlag, pp. 107128.Google Scholar
Jolicoeur, S. and O’Carroll, S. (2007). Sandy barriers, climate change and long-term planning of strategic coastal infrastructures, Îles-de-la-Madeleine, Gulf of St. Lawrence (Québec, Canada). Landscape and Urban Planning 81: 287298.CrossRefGoogle Scholar
Jones, M. L. M., Wallace, H. L., Norris, D., et al. (2004). Changes in vegetation and soil characteristics in coastal sand dunes along a gradient of atmospheric nitrogen deposition. Plant Biology 6: 598605.Google Scholar
Jones, M. L. M., Norman, K., and Rhind, P. M. (2010). Topsoil inversion as a restoration measure in sand dunes, early results from a UK field-trial. Journal of Coastal Conservation 14: 139151.Google Scholar
Jones, S. R. and Magnun, W. R. (2001). Beach nourishment and public policy after Hurricane Floyd: where do we go from here? Ocean & Coastal Management 44: 207220.Google Scholar
Judd, F. W., Lonard, R. I., Everitt, J. H., and Villarreal, R. (1989). Effects of vehicular traffic in the secondary dunes and vegetated flats of South Padre Island, Texas. In Coastal Zone 89. New York: American Society of Civil Engineers, pp. 46344645.Google Scholar
Jungerius, P. D., Koehler, H., Kooijman, A. M., Mücher, H. J., and Graefe, U. (1995). Response of vegetation and soil ecosystem to mowing and sod removal in the coastal dunes “Zwanenwater” The Netherlands. Journal of Coastal Conservation 1: 316.Google Scholar
Kaczkowski, H. L., Kana, T. W., Traynum, S. B., and Visser, R. (2018). Beach-fill equilibrium and dune growth at two large-scale nourishment sites. Ocean Dynamics 68: 11911206.Google Scholar
Kana, T. W. and Kaczkowski, H. L. (2019). Myrtle Beach: a history of shore protection and beach restoration. Shore and Beach 87(3): 1334.Google Scholar
Kana, T. W., Traynum, S. B., Gaudiano, D., Kaczkowski, H. L., and Hair, T. (2013). The physical condition of South Carolina beaches 1980–2010. Journal of Coastal Research SI69: 6182.Google Scholar
Kar, D., Rhode, R., Snider, N. P., and Robichaux, E. (2020). Measuring success through outcome indicators for restoration efforts in Louisiana. Journal of Coastal Research SI95: 11281133.Google Scholar
Katz, E. (1999). A pragmatic re-consideration of anthropocentrism. Environmental Ethics 21: 377390.Google Scholar
Keddy, P. A. (1981). Experimental demography of a dune annual: Cakile edentula growing along an environmental gradient in Nova Scotia. Journal of Ecology 69: 615630.Google Scholar
Kelly, J. F. (2014). Effects of human activities (raking, scraping, off-road vehicles) and natural resource protections on the spatial distribution of beach vegetation and related shoreline features in New Jersey. Journal of Coastal Conservation 18: 383398.Google Scholar
Kelly, J. F. (2016). Assessing the spatial compatibility of recreational activities with beach vegetation and wrack in New Jersey: prospects for compromise management. Ocean & Coastal Management 123: 917.Google Scholar
Kennedy, A., Rogers, S., Sallenger, A., et al. (2011). Building destruction from waves and surge on the Bolivar Peninsula during Hurricane Ike. Journal of Waterway, Port, Coastal, and Ocean Engineering 137: 132141.Google Scholar
Kenny, A. J. and Rees, H. L. (1994). The effects of marine gravel extraction on the macrobenthos: early post-dredging recolonization. Marine Pollution Bulletin 28: 442447.Google Scholar
Kenny, A. J. and Rees, H. L. (1996). The effects of marine gravel extraction on the macrobenthos: results 2 years post-dredging. Marine Pollution Bulletin 32: 615622.Google Scholar
Kessler, R. (2008). Sand dune stabilization at Pineda Ocean Club. Land and Water 52(3): 1322.Google Scholar
Ketner-Oostra, R. and Sýkora, K. V. (2000). Vegetation succession and lichen diversity on dry coastal calcium-poor dunes and the impact of management experiments. Journal of Coastal Conservation 6: 191206.Google Scholar
Kilibarda, Z., Graves, N., Dorton, M., and Dorton, R. (2014). Changes in beach gravel lithology caused by anthropogenic activities along the southern coast of Lake Michigan. Environmental Earth Science 71: 12491266.Google Scholar
Kirk, R. M. (1980). Mixed sand and gravel beaches: morphology, processes and sediments: Progress in Physical Geography 4: 189210.Google Scholar
Klein, A. H. F., Aroujo, R. S., Polette, M., et al. (2009). Ameliorative strategies at Balnéario Piçarras Beach. In Williams, A. and Micallef, A. (Eds.), Beach Management: Principles & Practice. London: Earthscan, pp. 247261.Google Scholar
Klein, R. J. T., Smit, M. J., Goosen, H., and Hulsbergen, C. H. (1998). Resilience and vulnerability – coastal dynamics or Dutch dikes? The Geographical Journal 164: 259268.Google Scholar
Klein, Y. L., Osleeb, J. P., and Viola, M. R. (2004). Tourism-generated earnings in the coastal zone: a regional analysis. Journal of Coastal Research 20: 10801088.Google Scholar
Klijn, J. A. (1990). The younger dunes in The Netherlands: chronology and causation. Catena Suppl 18: 89100.Google Scholar
Knevel, I. C., Venema, H. G., and Lubke, R. A. (2002). The search for indigenous dune stabilizers: germination requirements of selected South African species. Journal of Coastal Conservation 8: 169178.Google Scholar
Knight, R. L. (1999). Private lands: the neglected geography. Conservation Biology 13: 223224.Google Scholar
Knutson, P. L. (1978). Planting guidelines for dune creation and stabilization. In Coastal Zone 78. New York: American Society of Civil Engineers, pp. 762779.Google Scholar
Kochnower, D., Reddy, S. M. W., and Flick, R. E. (2015). Factors influencing local decisions to use habitats to protect coastal communities from hazards. Ocean & Coastal Management 116: 277290.Google Scholar
Koehler, H., Munderloh, E., and Hofmann, S. (1995). Soil microarthropods (Acari and Collembola) from beach and dune: characteristics and ecosystematic context. In Salman, A. H. P. M., Berends, H., and Bonazountas, M. (Eds.), Coastal Management and Habitat Conservation. Leiden: EUCC, pp. 371383.Google Scholar
Komar, P. D., Allen, J. C., and Winz, R. (2003). Cobble beaches – the “design with nature” approach for shore protection. In Coastal Sediments 03. New York: American Society of Civil Engineers, pp. 113.Google Scholar
Kombiadou, K., Costas, S., Carrasco, A. R., Plomaritis, T. A., Ferreira, Ó., and Matias, A. (2019). Bridging the gap between resilience and geomorphology of complex coastal systems. Earth-Science Reviews 198: 102934.Google Scholar
Konlechner, T. M. and Hilton, M. J. (2009). The potential for marine dispersal of Ammophila arenaria (marram grass) rhizome in New Zealand. Journal of Coastal Research SI56: 434437.Google Scholar
Konlechner, T. M., Hilton, M. J., and Arens, S. M. (2014). Transgressive dune development following deliberate de-vegetation for dune restoration in the Netherlands and New Zealand. Dynamic Environments 33: 141154.Google Scholar
Konlechner, T. M., Ryu, W., Hilton, M. J., and Sherman, D. J. (2015a). Evolution of foredune texture following dynamic restoration, Doughboy Bay, Stewart Island, New Zealand. Aeolian Research 19: 203214.Google Scholar
Konlechner, T. M., Hilton, M. J., and Lord, J. M. (2015b). Plant community response following the removal of the invasive Lupinus arboreus in a coastal dune system. Restoration Ecology 23: 607614.Google Scholar
Kooijman, A. M. (2004). Environmental problems and restoration measures in coastal dunes in The Netherlands. In Martínez, M. L. and Psuty, N. P. (Eds.), Coastal Dunes, Ecology and Conservation. Berlin: Springer-Verlag, pp. 243258.Google Scholar
Kooijman, A. M. and de Haan, M. W. A. (1995). Grazing as a measure against grass encroachment in Dutch dry dune grassland: effects on vegetation and soil. Journal of Coastal Conservation 1: 127134.Google Scholar
Kooijman, A. M. and Smit, A. (2001). Grazing as a measure to reduce nutrient availability and plant productivity in acid dune grasslands and pine forests in The Netherlands. Ecological Engineering 17: 6377.Google Scholar
Kooijman, A. M., van Til, M., Noordijk, E., Remke, E., and Kalbitz, K. (2017). Nitrogen deposition and grass encroachment in calcareous and acidic grey dunes (H2130) in NW-Europe. Biological Conservation 212: 406415.Google Scholar
Kopp, R. E., Gilmore, E. A., Little, C. M., Lorenzo-Trueba, J., Ramenzoni, V. C., and Sweet, W. V. (2019). Usable science for managing the risks of sea-level rise. Earth’s Future 7: 12351269.Google Scholar
Koske, R. E., Gemma, J. N., Corkidi, L., Sigüenza, C., and Rincón, E. (2004). Arbuscular mycorrhizas in coastal dunes. In Martínez, M. L. and Psuty, N. P. (Eds.), Coastal Dunes, Ecology and Conservation. Berlin: Springer-Verlag, pp. 173187.Google Scholar
Koster, M. J. and Hillen, R. (1995). Combat erosion by law: coastal defense policy for The Netherlands. Journal of Coastal Research 11: 12211228.Google Scholar
Kousky, C. (2014). Managing shoreline retreat: a US perspective. Climatic Change 124: 920.Google Scholar
Kowalewski, M., Domènech, R., and Martinell, J. (2014). Vanishing clams on an Iberian beach: local consequences and global implications of accelerating loss of shells to tourism. PLoS ONE 9: e83615.Google Scholar
Kratzmann, M. G. and Hapke, C. J. (2012). Quantifying anthropogenically driven morphologic changes on a barrier island: Fire Island National Seashore. Journal of Coastal Research 28: 7688.Google Scholar
Kraus, N. C. and Rankin, K. L. (2004). Functioning and design of coastal groins: the interaction of groins and the beach – process and planning. Journal of Coastal Research SI33.Google Scholar
Krelling, A. P., Williams, A. T., and Turra, A. (2017). Differences in perception and reaction of tourist groups to beach marine debris that can influence loss of tourism revenue in coastal areas. Marine Policy 85: 8799.Google Scholar
Kriesel, W., Keeler, A., and Landry, C. (2004). Financing beach improvements: comparing two approaches on the Georgia coast. Coastal Management 32: 433447.Google Scholar
Krogh, M. G. and Schweitzer, S. H. (1999). Least terns nesting on natural and artificial habitats in Georgia, USA. Waterbirds 22: 290296.Google Scholar
Kuang, C., Mao, X., Gu, J., et al. (2019). Morphological processes of two artificial submerged shore-parallel sandbars for beach nourishment in a nearshore zone. Ocean & Coastal Management 179: 104870.Google Scholar
Kumar, A., Seralathan, P., and Jayappa, K. S. (2009). Distribution of coastal cliffs in Kerala, India: their mechanisms of failure and related human engineering response. Environmental Geology 58: 815832.Google Scholar
Kuriyama, Y., Mochizuki, N., and Nakashima, T. (2005). Influence of vegetation on Aeolian sand transport rate from a backshore to a foredune at Hasaki, Japan. Sedimentology 52: 11231132.Google Scholar
Kutiel, P. B. (2013). Restoration of coastal sand dunes for conservation of biodiversity: the Israeli experience. In: Martínez, M. L., Gallego-Fernández, J. B., and Hesp, P. A. (Eds.), Restoration of Coastal Dunes. New York: Springer, pp. 173185.Google Scholar
Kutiel, P., Peled, Y., and Geffen, E. (2000). The effect of removing shrub cover on annual plants and small mammals in a coastal sand dune ecosystem. Biological Conservation 94: 235242.Google Scholar
Lamb, F. H. (1898). Sand-dune reclamation on the Pacific Coast. The Forester 4: 141142.Google Scholar
Lamberti, A. and Mancinelli, A. (1996). Italian experience on submerged barriers as beach defence structures. In Edge, B. L. (Ed.), Coastal Engineering 1996. New York: American Society of Civil Engineers, pp. 23522365.Google Scholar
Lamberti, A., Archetti, R., Kramer, M., Paphilitis, D., Mosso, C., and Di Risio, M. (2005). European experience of low crested structures for coastal management. Coastal Engineering 52: 841866.Google Scholar
Lammerts, E. J., Grootjans, A., Stuyfzand, P., and Sival, F. (1995). Endangered dune slack plants: gastronovers in need of mineral water. In Salman, A. H. P. M., Berends, H., and Bonazountas, M. (Eds.), Coastal Management and Habitat Conservation. Leiden: EUCC, pp. 355369.Google Scholar
Lapointe, M., Gurney, G. G., and Cumming, G. S. (2020). Urbanization alters ecosystem service preferences in a small island developing state. Ecosystem Services 43: 101109.Google Scholar
Larson, M. and Kraus, N. C. (2000). Representation of non-erodible (hard) bottoms in beach profile change modeling. Journal of Coastal Research 16: 114.Google Scholar
Latsoudis, P. K. (1996). The natural and artificial dunes of Cape Epanomi. In Salman, A. H. P. M., Langeveld, M. J., and Bonazountas, M. (Eds.), Coastal Management and Habitat Conservation. Leiden: EUCC, pp. 5557.Google Scholar
Lawrenz-Miller, S. (1991). Grunion spawning versus beach nourishment: nursery or burial ground. In Coastal Zone 91. New York: American Society of Civil Engineers, pp. 21972208.Google Scholar
Lazarus, E. D. and Goldstein, E. B. (2019). Is there a bulldozer in your model? Journal of Geophysical Research: Earth Surface 124: 696699.Google Scholar
Lazarus, E. D., McNamara, D. E., Smith, M. D., Gopalakrishnan, S., and Murray, A. B. (2011). Emergent behavior in a coupled economic and coastline model for beach nourishment. Nonlinear Processes in Geophysics 18: 989999.Google Scholar
Lazarus, E. D., Ellis, M. A., Murray, A. B., and Hall, D. M. (2016). An evolving research agenda for human-coastal systems. Geomorphology 256: 8190.Google Scholar
Leafe, R., Pethick, J., and Townend, I. (1998). Realizing the benefits of shoreline management. The Geographical Journal 164: 282290.Google Scholar
Ledoux, L., Cornell, S., O’Riordan, T., Harvey, R., and Banyard, L. (2005). Towards sustainable flood and coastal management: identifying drivers of, and obstacles to, managed realignment. Land Use Policy 22(2): 129144.Google Scholar
Lee, E. M. (1993). The political ecology of coastal planning and management in England and Wales: policy responses to the implications of sea-level-rise. The Geographical Journal 159: 169178.Google Scholar
Lee, E. M. (1998). Problems associated with the prediction of cliff recession rates for coastal defence and conservation. In Hooke, J. (Ed.), Coastal Defence and Earth Science Conservation. Bath: The Geological Society, pp. 4657.Google Scholar
Leege, L. M. and Kilgore, J. S. (2014). Recovery of foredune and blowout habitats in a freshwater dune following removal of invasive Austrian pine (Pinus nigra). Restoration Ecology 22: 641648.Google Scholar
Leege, L. M. and Murphy, P. G. (2000). Growth of the non-native Pinus nigra in four habitats on the sand dunes of Lake Michigan. Forest Ecology and Management 126: 191200.Google Scholar
Leewis, L., van Bodegom, P. M., Rozema, J., and Janssen, G. M. (2012). Does beach nourishment have long-term effects on intertidal macroinvertebrate species abundance? Estuarine, Coastal and Shelf Science 113: 172181.Google Scholar
Lehrer, D., Becker, N., and Kutiel, P. B. (2013). The value of coastal sand dunes as a measure to plan an optimal policy for invasive plant species: the case of the Acacia saligna at the Nizzanim LTER Coastal Sand Dune Nature Reserve, Israel. In: Martínez, M. L., Gallego-Fernández, J. B., and Hesp, P. A. (Eds.), Restoration of Coastal Dunes. New York: Springer, pp. 273288.Google Scholar
Lemauviel, S. and Roze, F. (2000). Ecological study of pine forest clearings along the French Atlantic sand dunes: perspectives of restoration. Acta Oecologica 21: 179192.Google Scholar
Lemauviel, S., Gallet, S., and Roze, F. (2003). Sustainable management of fixed dunes: example of a pilot site in Brittany, France. Comptes Rendus Biologies 326: S183S191.Google Scholar
Lentz, E. E., Thieler, E. R., Plant, N. G., Stippa, S. R., Horton, R. M., and Gesch, D. B. (2016). Evaluation of dynamic coastal response to sea-level rise modifies inundation likelihood. Nature Climate Change 6: 696701.Google Scholar
Li, B. and Sherman, D. J. (2015). Aerodynamics and morphodynamics of sand fences: a review. Aeolian Research 17: 3348.Google Scholar
Li, D., van de Werfhorst, L. C., Dunne, T., Devarajan, N., Gomez Ayala, T., and Holden, P. A. (2020). Surf zone microbiological water quality following emergency beach nourishment using sediments from a catastrophic debris flow. Water Research 176: 115733.Google Scholar
Light, A. and Higgs, E. S. (1996). The politics of ecological restoration. Environmental Ethics 18: 227247.Google Scholar
Lin, P. C-P., Hansen, I., and Sasso, R. H. (1996). Combined sand bypassing and navigation improvements at Hillsboro Inlet, Broward County, Florida: the importance of a regional approach. In Tait, L. S. (Ed.), The Future of Beach Nourishment. Tallahassee: Florida Shore and Beach Preservation Association, pp. 4359.Google Scholar
Lindeman, K. C. and Snyder, D. B. (1999). Nearshore hardbottom fishes of southeast Florida and effects of habitat burial caused by dredging. Fishery Bulletin 97: 508525.Google Scholar
Lithgow, D., Martínez, M. L., Gallego-Fernández, J. B., et al. (2013). Linking restoration ecology with coastal dune restoration. Geomorphology 199: 214224.Google Scholar
Lithgow, D., Martínez, M. L., and Gallego-Fernández, J. B. (2014). The “ReDune” index (Restoration of coastal Dunes Index) to assess the need and viability of coastal dune restoration. Ecological Indicators 49: 178187.Google Scholar
Liu, G., Feng, C., Hongshuai, Q., et al. (2019). A method to nourished beach stability assessment: the case of China. Ocean & Coastal Management 177: 166178.Google Scholar
Long, Z. T., Fegley, S. R., and Peterson, C. H. (2013). Fertilization and plant diversity accelerate primary succession and restoration of dune communities. Plant Ecology 214: 14191429.Google Scholar
Looney, P. B. and Gibson, D. J. (1993). Vegetation monitoring of beach nourishment. In Stauble, D. K. and Kraus, N. C. (Eds.), Beach Nourishment: Engineering and Management Considerations. New York: American Society of Civil Engineers, pp. 226241.Google Scholar
Lorang, M. S. (2002). Predicting the crest height of a gravel beach. Geomorphology 48: 87101.Google Scholar
Lorenzoni, I. and Hulme, M. (2009). Believing is seeing: laypeople’s views of future socio-economic and climate change in England and in Italy. Public Understanding of Science 18: 383400.Google Scholar
Lortie, C. J. and Cushman, J. H. (2007). Effects of a directional abiotic gradient on plant community dynamics and invasion in a coastal dune system. Journal of Ecology 95: 468481.Google Scholar
Lubke, R. A. (2004). Vegetation dynamics and succession on sand dunes of the eastern coasts of Africa. In Martínez, M. L. and Psuty, N. P. (Eds.), Coastal Dunes, Ecology and Conservation. Berlin: Springer-Verlag, pp. 6784.Google Scholar
Lubke, R. A. (2013). Restoration of dune ecosystems following mining in Madagascar and Namibia: contrasting restoration approaches adopted in regions of high and low human population density. In Martínez, M. L., Gallego-Fernández, J. B., and Hesp, P. A. (Eds.), Restoration of Coastal Dunes. New York: Springer, pp. 199215.Google Scholar
Lubke, R. A. and Avis, A. M. (1998). A review of the concepts and application of rehabilitation following heavy mineral dune mining. Marine Pollution Bulletin 37: 546557.Google Scholar
Lubke, R. A. and Hertling, U. M. (2001). The role of European marram grass in dune stabilization and succession near Cape Agulhas, South Africa. Journal of Coastal Conservation 7: 171182.Google Scholar
Lubke, R. A., Avis, A. M., and Hellstrom, G. B. (1995). Current status of coastal zone management in the Eastern Cape region, South Africa. In Salman, A. H. P. M., Berends, H., and Bonazountas, M. (Eds.), Coastal Management and Habitat Conservation. Leiden: EUCC, pp. 239260.Google Scholar
Lubke, R. A., Avis, A. M., and Moll, J. B. (1996). Post-mining rehabilitation of coastal sand dunes in Zululand, South Africa. Landscape and Urban Planning 34: 335345.Google Scholar
Lück-Vogel, M., and Mbolambi, C. (2018). Assessment of coastal Strandveld integrity using WorldView-2 imagery in False Bay, South Africa. South African Journal of Botany 116: 150157.Google Scholar
Lucrezi, S., and van der Walt, M. F. (2016). Beachgoers’ perceptions of sandy beach conditions: demographic and attitudinal influences, and the implications for beach ecosystem management. Journal of Coastal Conservation 20: 8196.Google Scholar
Ludka, B. C., Guza, R. T., and O’Reilly, W. C. (2018). Nourishment evolution and impacts at four southern California beaches: a sand volume analysis. Coastal Engineering 136: 96105.Google Scholar
Luisetti, T., Turner, R. K., Bateman, I. J., Morse-Jones, S., Adams, C., and Fonseca, L. (2011). Coastal and marine ecosystem services evaluation for policy and management: managed realignment case studies in England. Ocean & Coastal Management 54: 212224.Google Scholar
Lundberg, A., Kapfer, J., and Maren, I. E. (2017). Reintroduced mowing can counteract biodiversity loss in abandoned meadows. Erdkunde 71: 127142.Google Scholar
Luo, S., Liu, Y., Jin, R., Ahang, J., and Wei, W. (2016). A guide to coastal management: benefits and lessons learned of beach nourishment practices in China over the past two decades. Ocean & Coastal Management 134: 207215.Google Scholar
Lutz, K. (1996). Studie zum Generalplan Küstenschutz und zur Rekultivierung von Salzgrasländern. Unpublished report on behalf of the WWF Germany, Ostseeschutz project office Stralsund.Google Scholar
Maes, D., Ghesquiere, A., Logie, M., and Bonte, D. (2006). Habitat and mobility of two threatened coastal dune insects: implications for conservation. Journal of Insect Conservation 10: 105115.Google Scholar
Malvárez-García, G., Pollard, J., and Hughes, R. (2002). Coastal Zone Management on the Costa del Sol: a small business perspective. Journal of Coastal Research SI36: 470482.Google Scholar
Manning, L. M., Peterson, C. H., and Fegley, S. R. (2013). Degradation of surf-fish foraging habitat driven by persistent sedimentological modifications caused by beach nourishment. Bulletin of Marine Science 89: 83106.Google Scholar
Manning, L. M., Peterson, C. H., and Bishop, M. J. (2014). Dominant macrobenthic populations experience sustained impacts from annual disposal of fine sediments on sandy beaches. Marine Ecology Progress Series 508: 115.Google Scholar
Manno, G., Anfuso, G., Messina, E., Williams, A. T., Suffo, M., and Liguori, V. (2016). Decadal evolution of coastline armouring along the Mediterranean Andalusia littoral (South of Spain). Ocean & Coastal Management 124: 8499.Google Scholar
Marcomini, S. C. and López, R. A. (2006). Evolution of a beach nourishment project at Mar del Plata. Journal of Coastal Research SI39: 834837.Google Scholar
Marinho, B., Coelho, C., Larson, M., and Hanson, H. (2018). Short- and long-term responses of nourishments: Barra-Vagueira coastal stretch, Portugal. Journal of Coastal Conservation 22: 475489.Google Scholar
Marqués, M. A., Psuty, N. P., and Rodriguez, R. (2001). Neglected effects of eolian dynamics on artificial beach nourishment: the case of Riells, Spain. Journal of Coastal Research 17: 694704.Google Scholar
Marsh, G. P. (1885). Earth as Modified by Human Action. New York: Charles Scribner.Google Scholar
Martin, K. L. and Adams, L. C. (2020). Effects of repeated sand replenishment projects on runs of a beach-spawning fish, the California grunion. Journal of Marine Science and Engineering 8: 178.Google Scholar
Martinez, G., Armaroli, C., Costas, S., Harley, M. D., and Paolisso, M. (2018). Experiences and results from interdisciplinary collaboration: utilizing qualitative information to formulate disaster risk reduction measures for coastal regions. Coastal Engineering 134: 6272.Google Scholar
Martínez, M. L. and García-Franco, J. G. (2004). Plant-plant interactions in coastal dunes. In Martínez, M. L. and Psuty, N. P. (Eds.), Coastal Dunes, Ecology and Conservation. Berlin: Springer-Verlag, pp. 205220.Google Scholar
Martínez, M. L., Maun, M. A., and Psuty, N. P. (2004). The fragility and conservation of the world’s coastal dunes: geomorphological, ecological, and socioeconomic perspectives. In Martínez, M. L. and Psuty, N. P. (Eds.), Coastal Dunes, Ecology and Conservation. Berlin: Springer-Verlag, pp. 355369.Google Scholar
Martínez, M. L., Chávez, V., Lithgow, D., and Silva, R. (2019). Integrating biophysical components in coastal engineering practices. Journal of Coastal Research SI92: 15.Google Scholar
Maslo, B., Handel, S. N., and Pover, T. (2011). Restoring beaches for Atlantic Coast piping plovers (Charadrius melodus): a classification and regression tree analysis of nest-site selection. Restoration Ecology 19: 194203.Google Scholar
Maslo, B., Leu, ., Pover, K., Weston, T., Gilby, M. A., , B. L., and Schlacher, T. A. (2019). Optimizing conservation benefits for threatened beach fauna following severe natural disturbances. Science of the Total Environment 649: 661671.Google Scholar
Mason, T. and Coates, T. T. (2001). Sediment transport processes on mixed beaches: a review for shoreline management. Journal of Coastal Research 17: 645657.Google Scholar
Mason, T. J. and French, K. (2007). Management regimes for a plant invader differentially impact resident communities. Biological Conservation 136: 246259.Google Scholar
Masselink, G. and Lazarus, E. D. (2019). Defining coastal resilience. Water 11: 2587.Google Scholar
Masselink, G. and Short, A. D. (1993). The effect of tide range on beach morphodynamics and morphology: a conceptual beach model. Journal of Coastal Research 9: 785800.Google Scholar
Masucci, G. D. and Reimer, J. D. (2019). Expanding walls and shrinking beaches: loss of natural coastline in Okinawa Island, Japan. PeerJ 7: e7520.Google Scholar
Mather, A. S. and Ritchie, W. (1977). The Beaches of the Highlands and Islands of Scotland. Perth: Countryside Commission for Scotland.Google Scholar
Mathew, M. J., Sautter, B., Ariffin, E. H., et al. (2020). Total vulnerability of the littoral zone to climate change-driven natural hazards in north Brittany, France. Science of the Total Environment 706: 135963.Google Scholar
Matias, A., Ferreira, Ó., Mendes, I., Dias, J. A., and Vila-Consejo, A. (2005). Artificial construction of dunes in the south of Portugal. Journal of Coastal Research 21: 472481.Google Scholar
Matsumoto, H., Young, A. P., and Guza, R. T. (2020). Observations of surface cobbles at two southern California beaches Marine Geology 419: 106049.Google Scholar
Maun, M. A. (1998). Adaptation of plants to burial in coastal sand dunes. Canadian Journal of Botany 76: 713738.Google Scholar
Maun, M. A. (2004). Burial of plants as a selective force in sand dunes. In Martínez, M. L. and Psuty, N. P. (Eds.), Coastal Dunes, Ecology and Conservation. Berlin: Springer-Verlag, pp. 119135.Google Scholar
Mauriello, M. N. (1989). Dune maintenance and enhancement: a New Jersey example. In Coastal Zone 89. New York: American Society of Civil Engineers, pp. 10231037.Google Scholar
Mauriello, M. N. (1991). Beach nourishment and dredging: New Jersey’s policies. Shore and Beach 59(3): 2528.Google Scholar
Mauriello, M. N. and Halsey, S. D. (1987). Dune building on a developed coast. In Coastal Zone 87. New York: American Society of Civil Engineers, pp. 13131327.Google Scholar
May, V. (2015). Coastal cliff conservation and management: the Dorset and east Devon coast world heritage site. Journal of Coastal Conservation 19: 821829.Google Scholar
McArdle, S. B. and McLachlan, A. (1992). Sand beach ecology: swash features relevant to the macrofauna. Journal of Coastal Research 8: 398407.Google Scholar
McIntyre, A. F. and Heath, J. A. (2011). Evaluating the effects of foraging habitat restoration on shorebird reproduction: the importance of performance criteria and comparative designs. Journal of Coastal Conservation 15: 151157.Google Scholar
McLachlan, A. (1985). The biomass of macro- and interstitial fauna on clean and wrack-covered beaches in Western Australia. Estuarine, Coastal and Shelf Science 21: 587599.Google Scholar
McLachlan, A. (1990). The exchange of materials between dune and beach systems. In Nordstrom, K. F., Psuty, N. P., and Carter, R. W. G. (Eds.), Coastal Dunes: Form and Process. Chichester: John Wiley & Sons, pp. 201215.Google Scholar
McLachlan, A. (1996). Physical factors in benthic ecology: effects of changing sand particle size on beach fauna. Marine Ecology Progress Series 131: 205217.Google Scholar
McLachlan, A. and Burns, M. (1992). Headland bypass dunes on the South African coast: 100 years of (mis)management. In Carter, R. W. G., Curtis, T. G. F., and Sheehy-Skeffington, M. J. (Eds.), Coastal Dunes: Geomorphology, Ecology and Management for Conservation. Rotterdam: A.A. Balkema, pp. 7179.Google Scholar
McLean, R. F. and Kirk, R. M. (1969). Relationship between grain size, size-sorting and fore-shore slope on mixed sand-shingle beaches. New Zealand Journal of Geology and Geophysics 12: 138155.Google Scholar
McLean, R. and Shen, J.-S. (2006). From foreshore to foredune: foredune development over the last 30 years at Moruya Beach, New South Wales, Australia. Journal of Coastal Research 22: 2836.Google Scholar
McLouth, M. E., Lapolla, J., and Bodge, K. (1994). Port Authority’s role in inlet management and beneficial use of dredged material. In Dredging ‘94. New York: American Society of Civil Engineers, pp. 971980.Google Scholar
McNamara, D. E., Gopalakrishnan, S., Smith, M. D., and Murray, A. B. (2015). Climate adaptation and policy-induced inflation of coastal property value. PLoS ONE 10: e0121278.Google Scholar
McNinch, J. E. and Wells, J. T. (1992). Effectiveness of beach scraping as a method of erosion control. Shore and Beach 60(1): 1320.Google Scholar
Melvin, S. M., Griffin, C. R., and MacIvor, L. H. (1991). Recovery strategies for piping plovers in managed coastal landscapes. Coastal Management 19: 2134.Google Scholar
Mendelssohn, I. A., Hester, M. W., Monteferrante, F. J., and Talbot, F. (1991). Experimental dune building and vegetative stabilization in a sand-deficient barrier island setting on the Louisiana coast, USA. Journal of Coastal Research 7: 137149.Google Scholar
Meyer-Arendt, K. J. (1990). Recreational business districts in Gulf of Mexico seaside resorts. Journal of Cultural Geography 11: 3955.Google Scholar
Meyer-Arendt, K. J. (1993). Geomorphic impacts of resort evolution along the Gulf of Mexico coast; applicability of resort cycle models. In Wong, P. P. (Ed.), Tourism vs Environment: The Case for Coastal Areas. Dordrecht: Kluwer Academic Publishers, pp. 125138.Google Scholar
Mielck, F., Hass, H. C., Michaelis, R., Sander, L., Papenmeier, S., and Wiltshire, K. H. (2019). Morphological changes due to marine aggregate extraction for beach nourishment in the German Bight (SE North Sea). Geo-Marine Letters 39: 4758.Google Scholar
Miller, D. L., Thetford, M., and Yager, L. (2001). Evaluating sand fence and vegetation for dune building following overwash by Hurricane Opal on Santa Rosa Island, Florida. Journal of Coastal Research 17: 936948.Google Scholar
Miller, D. L., Thetford, M., Dupree, J., and Atwood, L. (2014). Influence of seasonal changes and shifting substrate on survival of restoration plantings of Schizachyrium maritimum (Gulf Bluestem) on Santa Rosa Island, Florida. Journal of Coastal Research 30: 237247.Google Scholar
Miller, K. G., Kopp, R. E., Horton, B. P., Browning, J. V., and Kemp, A. C. (2013). A geological perspective on sea-level rise and its impacts along the U.S. mid-Atlantic coast. Earth’s Future 1: 318.Google Scholar
Millett, J. and Edmondson, S. (2013). The impact of 36 years of grazing management on vegetation dynamics in dune slacks. Journal of Applied Ecology 50: 13671376.Google Scholar
Milton, S. L., Schulman, A. A., and Lutz, P. L. (1997). The effect of beach nourishment with aragonite versus silicate sand on beach temperature and loggerhead sea turtle nesting success. Journal of Coastal Research 13: 904915.Google Scholar
Minerals Management Service. (2001). Development and Design of Biological and Physical Monitoring Protocols to Evaluate the Long-Term Impacts of Offshore Dredging Operations on the Marine Environment. U.S. Department of the Interior, Minerals Management Service Final Report MMS 2001-089.Google Scholar
Minteer, B. A. and Manning, R. E. (1999). Pragmatism in environmental ethics: democracy, pluralism, and the management of nature. Environmental Ethics 21: 191207.Google Scholar
Mireille, E., Mendoza, E., and Silva, R. (2020). Micro sand engine beach stabilization strategy at Puerto Morelos, Mexico. Journal of Marine Science and Engineering 8: 247263.Google Scholar
Miselis, J. L., Andrews, B. D., Nicholson, R. S., Defne, Z., Ganju, N. K., and Navoy, A. (2016). Evolution of mid-Atlantic coastal and back-barrier estuary environments in response to a hurricane: implications for barrier-estuary connectivity. Estuaries and Coasts 39: 916934.Google Scholar
Mitsch, W. J. (1998). Ecological engineering – the 7-year itch. Ecological Engineering 10: 119130.Google Scholar
Mitteager, W. A., Burke, A., and Nordstrom, K. F. (2006). Landscape features and restoration potential on private shorefront lots in New Jersey, USA. Journal of Coastal Research SI39: 890897.Google Scholar
Moore, R. and Davis, G. (2015). Cliff instability and erosion management in England and Wales. Journal of Coastal Conservation 19: 771784.Google Scholar
Morand, P. and Merceron, M. (2005). Macroalgal populations and sustainability. Journal of Coastal Research 21: 10091020.Google Scholar
Moreno-Casasola, P. (1986). Sand movement as a factor in the distribution of plant communities in a coastal dune system. Vegetatio 65: 6776.Google Scholar
Moreno-Casasola, P. (2004). A case study of conservation and management of tropical sand dune systems: La Mancha-El Llano. In Martínez, M. L. and Psuty, N. P. (Eds.), Coastal Dunes, Ecology and Conservation. Berlin: Springer-Verlag, pp. 319333.Google Scholar
Moreno-Casasola, P., Martínez, M. L., Castillo-Campos, G., and Campos, A. (2013). The impacts on natural vegetation following the establishment of exotic Casuarina plantations. In Martínez, M. L., Gallego-Fernández, J. B., and Hesp, P. A. (Eds.), Restoration of Coastal Dunes. New York: Springer, pp. 217233.Google Scholar
Morgan, R. (1999). Preferences and priorities of recreational beach users in Wales, UK. Journal of Coastal Research 15: 653667.Google Scholar
Morgan, R. and Williams, A. T. (1999). Video panorama assessment of beach landscape aesthetics on the coast of Wales. Journal of Coastal Conservation 5: 1322.Google Scholar
Morris, R. K. A. (2012). Managed realignment: a sediment management paradigm. Ocean & Coastal Management 65: 5966.Google Scholar
Morris, R. L., Konlechner, T. M., Ghisalberti, M., and Swearer, S. E. (2019). From grey to green: efficacy of eco-engineering solutions for nature-based coastal defence. Global Change Biology 24: 18271842.Google Scholar
Morton, R. A. (2002). Factors controlling storm impacts on coastal barriers and beaches – a preliminary basis for near real-time forcasting. Journal of Coastal Research 18: 486501.Google Scholar
Moschella, P. S., Abbiati, M., Aberg, P., et al. (2005). Low-crested coastal defence structures as artificial habitats for marine life: using ecological criteria in design. Coastal Engineering 52: 10531071.Google Scholar
Moses, C. A. and Williams, R. B. G. (2008). Artificial beach recharge: the South East England experience. Zeitschrift für Geomorphologie 52(Suppl. 3): 107124.Google Scholar
Moss, D. and McPhee, D. P. (2006). The impacts of recreational four-wheel driving on the abundance of the ghost crab (Ocypode cordimanus) on a subtropical sandy beach in SE Queensland. Coastal Management 34: 133140.Google Scholar
Mossman, H. L., Davy, A. J., and Grant, A. (2012). Does managed realignment create saltmarshes with “equivalent biological characteristics” to natural reference sites? Journal of Applied Ecology 49: 14461456.Google Scholar
Mulder, J. P. M., van de Kreeke, J., and van Vessem, P. (1994). Experimental shoreface nourishment, Terschelling (NL). In Coastal Engineering: Proceedings of the Twenty-Fourth Coastal Engineering Conference. New York: American Society of Civil Engineers, pp. 28862899.Google Scholar
Muñoz-Perez, J. J., Lopez de San Roman-Blanco, B., Gutierrez-Mas, J. M., Moreno, L., and Cuena, G. J. (2001). Cost of beach maintenance in the Gulf of Cadiz (SW Spain). Coastal Engineering 42: 143153.Google Scholar
Muñoz-Reinoso, J. C. (2003). Juniperus oxycedrus ssp. macrocarpa in SW Spain: ecology and conservation problems. Journal of Coastal Conservation 9: 113122.Google Scholar
Muñoz-Reinoso, J. C. (2004). Diversity of maritime juniper woodlands. Forest Ecology and Management 192: 267276.Google Scholar
Muñoz-Reinoso, J. C., Saavedra Azqueta, C., and Redondo Morales, I. (2013). Restoration of Andalusian coastal juniper woodlands. In Martínez, M. L., Gallego-Fernández, J. B., and Hesp, P. A. (Eds.), Restoration of Coastal Dunes. New York: Springer, pp. 145158.Google Scholar
Murphy, A. L., Singers, N. J. D., and Rapson, G. L. (2019). Created dune slack wetlands effectively host rare early successional turf communities in a dynamic dunefield, New Zealand. Journal of Coastal Conservation 23: 203225.Google Scholar
Murray, A. B., Gopalakrishnan, S., McNamara, D., and Smith, M. D. (2013). Progress in coupling models of human and coastal landscape change. Computers and Geosciences 53: 3033.Google Scholar
Myatt, L. B., Scrimshaw, M. D., and Lester, J. N. (2003). Public perceptions and attitudes towards a current managed realignment scheme: Brancaster West Marsh, North Norfolk, U.K. Journal of Coastal Research 19: 278286.Google Scholar
Myers, M. R., Barnard, P. L., Beighley, E., et al. (2019). A multidisciplinary coastal vulnerability assessment for local government focused on ecosystems, Santa Barbara area, California. Ocean & Coastal Management 182: 104921.Google Scholar
Nachite, D., Maziane, F., Anfuso, G., and Macias, A. (2018). Beach litter characteristics along the Moroccan Mediterranean coast: implications for coastal zone management. In Botero, C. M., Cervantes, O., and Finkl, C. W. (Eds.), Beach Management Tools – Concepts, Methodologies and Case Studies. Cham, Switzerland: Springer International Publishing, pp. 795819.Google Scholar
Nairn, R., Johnson, J. A., Hardin, D., and Michel, J. (2004). A biological and physical monitoring program to evaluate long-term impacts from sand dredging operations in the United States outer continental shelf. Journal of Coastal Research 20: 126137.Google Scholar
Narayan, S., Pontee, N., Beck, M. W., and Hosking, A. H. (2016a). Nature based solutions: lessons from around the world. In Baptiste, A. (Ed.), Coastal Management: Changing Coast, Changing Climate, Changing Minds. International Coastal Management Conference. London: ICE Publishing, pp. 651662.Google Scholar
Narayan, S., Beck, M. W., Reguero, B. G., et al. (2016b). The effectiveness, costs and coastal protection benefits of natural and nature-based defenses. PLoS ONE 11: e0154735.Google Scholar
National Park Service. (2005). Breezy Point District Adaptive Management Plan: Environmental Assessment. Jamaica Bay Unit: NPS Gateway National Recreation Area.Google Scholar
National Park Service. (2011). Assateague Island National Seashore General Management Plan/Environmental Impact Statement. Newsletter 2, Summer 2011. Berlin: Assateague Island National Seashore.Google Scholar
National Research Council. (1995). Beach Nourishment and Protection. Washington, DC: National Academy Press.Google Scholar
National Research Council. (2007). Mitigating Shore Erosion along Sheltered Coasts. Washington, DC: National Academy Press.Google Scholar
National Research Council. (2014). Reducing Coastal Risk on the East and Gulf Coasts. Washington, DC: National Academy Press.Google Scholar
Nature Conservancy Council. (1991). A Guide to the Selection of Appropriate Coast Protection Works for Geological SSSIs. Peterborough: Nature Conservancy Council.Google Scholar
Naveh, Z. (1998). Ecological and cultural landscape restoration and the cultural evolution towards a post-industrial symbiosis between human society and nature. Restoration Ecology 6: 135143.Google Scholar
Naylor, L. A., Viles, H. A., and Carter, N. E. A. (2002). Biogeomorphology revisited: looking towards the future. Geomorphology 47: 314.Google Scholar
Nelson, W. G. (1989). Beach nourishment and hardbottom habitats: the case for caution. In Tait, L. S. (Ed.), Proceedings of the 1989 National Conference on Beach Preservation Technology. Tallahassee: Florida Shore and Beach Preservation Association, pp. 109116.Google Scholar
Nelson, W. G. (1993). Beach restoration in the southeastern US: environmental effects and biological monitoring. Ocean & Coastal Management 19: 157182.Google Scholar
Newell, R. C., Hitchcock, D. R., and Seiderer, L. J. (1999). Organic enrichment associated with outwash from marine aggregates dredging: a probable explanation for surface sheens and enhanced benthic production in the vicinity of dredging operations. Marine Pollution Bulletin 38: 809818.Google Scholar
Newell, R. C., Seiderer, L. J., Simpson, N. M., and Robinson, J. E. (2004). Impacts of marine aggregate dredging on benthic macrofauna of the south coast of the United Kingdom. Journal of Coastal Research 20: 115125.Google Scholar
Nicholls, R. J. and Branson, J. (1998). Coastal Resilience and planning for an uncertain future: an introduction. The Geographical Journal 164: 255258.Google Scholar
Nicholls, R. J. and Hoozemans, F. M. J. (1996). The Mediterranean: vulnerability to coastal implications of climate change. Ocean & Coastal Management 31: 105132.Google Scholar
Niven, R. J. and Bardsley, D. K. (2013). Planned retreat as a management response to coastal risk: a case study from the Fleurieu Peninsula, South Australia. Regional Environmental Change 13: 193209.Google Scholar
Nolet, C., and Riksen, M. J. P. M. (2019). Accommodation space indicates dune development potential along an urbanized and frequently nourished coastline. Earth Surface Dynamics 7: 129145.Google Scholar
Nordstrom, K. F. (1990). The concept of intrinsic value and depositional coastal landforms. Geographical Review 80: 6881.Google Scholar
Nordstrom, K. F. (1992). Estuarine Beaches. London: Elsevier Applied Science.Google Scholar
Nordstrom, K. F. (1994). Beaches and dunes of human-altered coasts. Progress in Physical Geography 18: 497516.Google Scholar
Nordstrom, K. F. (2000). Beaches and Dunes of Developed Coasts. Cambridge: Cambridge University Press.Google Scholar
Nordstrom, K. F. (2003). Restoring naturally functioning beaches and dunes on developed coasts using compromise management solutions: an agenda for action. In Dallmeyer, D. (Ed.), Values at Sea: Ethics for the Marine Environment. Athens: University of Georgia Press, pp. 204229.Google Scholar
Nordstrom, K. F. (2005). Beach nourishment and coastal habitats: research needs for improving compatibility. Restoration Ecology 13: 215222.Google Scholar
Nordstrom, K. F. (2008). Beach and Dune Restoration. Cambridge: Cambridge University Press.Google Scholar
Nordstrom, K. F. (2014). Living with shore protection structures: a review. Estuarine, Coastal and Shelf Science 150: 1123.Google Scholar
Nordstrom, K. F. (2019). Coastal dunes with resistant cores. Journal of Coastal Conservation 23: 227237.Google Scholar
Nordstrom, K. F. and Arens, S. M. (1998). The role of human actions in evolution and management of foredunes in The Netherlands and New Jersey, USA. Journal of Coastal Conservation 4: 169180.Google Scholar
Nordstrom, K. F. and Jackson, N. L. (1995). Temporal scales of landscape change following storms on a human-altered coast, New Jersey, USA. Journal of Coastal Conservation 1: 5162.Google Scholar
Nordstrom, K. F. and Jackson, N. L. (2003). Alternative restoration outcomes for dunes on intensively developed coasts. In Özhan, E. (Ed.), MEDCOAST ‘03. Ankara: MEDCOAST Secretariat, pp. 14691478.Google Scholar
Nordstrom, K. F. and Jackson, N. L. (2013). Removing shore protection structures to facilitate migration of landforms and habitats on the bayside of a barrier spit. Geomorphology 199: 179191.Google Scholar
Nordstrom, K. F. and Jackson, N. L. (2018). Constraints on restoring landforms and habitats on storm-damaged shorefront lots in New Jersey. Ocean & Coastal Management 155: 1523.Google Scholar
Nordstrom, K. F. and Lotstein, E. L. (1989). Conflicting scientific, managerial, and societal perspectives on resource use of dynamic coastal dunes, Geographical Review 79: 112.Google Scholar
Nordstrom, K. F. and Mauriello, M. N. (2001). Restoring and maintaining naturally-functioning landforms and biota on intensively developed barrier islands under a no-retreat scenario. Shore and Beach 69(3): 1928.Google Scholar
Nordstrom, K. F. and McCluskey, J. M. (1985). The effects of houses and sand fences on the eolian sediment budget at Fire Island, New York. Journal of Coastal Research l: 3946.Google Scholar
Nordstrom, K. F., Lampe, R., and Vandemark, L. M. (2000). Re-establishing naturally-functioning dunes on developed coasts. Environmental Management 25: 3751.Google Scholar
Nordstrom, K. F., Jackson, N. L., Bruno, M. S., and de Butts, H. A. (2002). Municipal initiatives for managing dunes in coastal residential areas: a case study of Avalon, New Jersey, USA. Geomorphology 47: 137152.Google Scholar
Nordstrom, K. F., Jackson, N. L., and Pranzini, E. (2004). Beach sediment alteration by natural processes and human actions: Elba Island, Italy. Annals of the Association of American Geographers 94: 794806.Google Scholar
Nordstrom, K. F., Hartman, J. M., Freestone, A. L., Wong, M., and Jackson, N. L. (2007a). Changes in topography and vegetation near gaps in a protective foredune. Ocean & Coastal Management 50: 945959.Google Scholar
Nordstrom, K. F., Jackson, N. L., Hartman, J. M., and Wong, M. (2007b). Aeolian sediment transport on a human-altered foredune. Earth Surface Processes and Landforms 32: 102115.Google Scholar
Nordstrom, K. F., Lampe, R., and Jackson, N. L. (2007c). Increasing the dynamism of coastal landforms by modifying shore protection methods: examples from the eastern German Baltic Sea Coast. Environmental Conservation 34: 205214.Google Scholar
Nordstrom, K. F., Pranzini, E., Jackson, N. L., and Coli, M. (2008). The marble beaches of Tuscany. Geographical Review 98: 280300.Google Scholar
Nordstrom, K. F., Jackson, N. L., and de Butts, H. L. (2009). A proactive programme for managing beaches and dunes on a developed coast: a case study of Avalon, New Jersey, USA. In Williams, A. and Micallef, A. (Eds.), Beach Management: Principles and Practice. London: Earth Scan, pp. 307316.Google Scholar
Nordstrom, K. F., Jackson, N. L., Kraus, N. C., et al. (2011). Enhancing geomorphic and biologic functions and values on backshores and dunes of developed shores: a review of opportunities and constraints. Environmental Conservation 38: 288302.Google Scholar
Nordstrom, K. F., Jackson, N. L., Freestone, A. L., Korotky, K. H., and Puleo, J. A. (2012). Effects of beach raking and sand fences on dune dimensions and morphology. Geomorphology 179: 106115.Google Scholar
Nordstrom, K. F., Armaroli, C., Jackson, N. L., and Ciavola, P. (2015). Opportunities and constraints for managed retreat on exposed sandy shores: examples from Emilia-Romagna, Italy. Ocean & Coastal Management 104: 1121.Google Scholar
Nordstrom, K. F., Jackson, N. L., and Roman, C. T. (2016). Facilitating landform migration by removing shore protection structures: opportunities and constraints. Environmental Science and Policy 66: 217226.Google Scholar
Nordstrom, K. F., Liang, B., Garilao, E. S., and Jackson, N. L. (2018). Topography, vegetation cover and below ground biomass of spatially constrained and unconstrained foredunes in New Jersey, USA. Ocean & Coastal Management 156: 117126.Google Scholar
Norton, B. G. and Steinemann, A. C. (2001). Environmental values and adaptive management. Environmental Values 10: 473506.Google Scholar
Norton, D. A. (2000). Conservation biology and private land: shifting the focus. Conservation Biology 14: 12211223.Google Scholar
Nourisson, D. H., Bessa, F., Scapini, F., and Marques, J. C. (2014). Macrofaunal community abundance and diversity and talitrid orientation as potential indicators of ecological long-term effects of a sand-dune recovery intervention. Ecological Indicators 36: 356366.Google Scholar
Novoa, A., González, L., Moravcová, L., and Pysek, P. (2013). Constraints to native plant species establishment in coastal dune communities invaded by Carpobrotus edulis: implications for restoration. Biological Conservation 164: 19.Google Scholar
Nuryanti, W. (1996). Heritage and postmodern tourism. Annals of Tourism Research 23: 249260.Google Scholar
O’Brien, M. K., Valverde, H. R., Trembanis, A. C., and Haddad, T. C. (1999). Summary of beach nourishment activity along the Great Lakes’ shoreline 1955–1996. Journal of Coastal Research 15: 206219.Google Scholar
O’Connell, T. O., Franze, C. D., Spalding, E. A., and Poirier, M. A. (2005). Biological resources of the Louisiana coast: Part 2. Coastal animals and habitat associations. Journal of Coastal Research SI44: 146161.Google Scholar
O’Donnell, J. E. D. (2017). Living shorelines: a review of literature relevant to New England coasts. Journal of Coastal Research 33: 435451.Google Scholar
O’Donnell, T. (2019). Coastal management and the political-legal geographies of climate change adaptation in Australia. Ocean & Coastal Management 175: 127135.Google Scholar
O’Neil, K. M. and van Abs, D. J. (Eds.). (2016). Taking Chances: The Coast after Hurricane Sandy. New Brunswick, NJ: Rutgers University Press.Google Scholar
Ochieng, C. A. and Erftemeijer, P. L. A. (1999). Accumulation of seagrass beach cast along the Kenyan coast: a quantitative assessment. Aquatic Botany 65: 221238.Google Scholar
Odériz, I., Knöchelmann, N., Silva, R., Feagin, R. A., Martínez, M. L., and Mendoza, E. (2020). Reinforcement of vegetated and unvegetated dunes by a rocky core: a viable alternative for dissipating waves and providing protection. Coastal Engineering 158: 103675.Google Scholar
Ofiara, D. D. and Brown, B. (1999). Assessment of economic losses to recreational activities from 1988 marine pollution events and assessment of economic losses from long-term contamination of fish within the New York Bight to New Jersey. Marine Pollution Bulletin 38: 9901004.Google Scholar
Ollerhead, J., Davidson-Arnott, R., Walker, I. J., and Mathew, S. (2013). Annual to decadal morphodynamics of the foredune system at Greenwich Dunes, Prince Edward Island, Canada. Earth Surface Processes and Landforms 38: 284298.Google Scholar
Orford, J. and Jennings, S. (1998). The importance of different time-scale controls on coastal management strategy: the problem of Porlock gravel barrier, Somerset, UK. In Hooke, J. (Ed.), Coastal Defense and Earth Science Conservation. Bath: The Geological Society, pp. 87102.Google Scholar
Orford, J. D. and Pethick, J. (2006). Challenging assumptions of future coastal habitat development around the UK. Earth Surface Processes and Landforms 31: 16251642.Google Scholar
Orr, M., Zimmer, M., Jelinski, D. E., and Mews, M. (2005). Wrack deposition on different beach types: spatial and temporal variation in the pattern of subsidy. Ecology 86: 14961507.Google Scholar
Osswald, F., Dolch, T., and Reise, K. (2019). Remobilizing stabilized island dunes for keeping up with sea level rise? Journal of Coastal Conservation 23: 675687.Google Scholar
Owens, J. S. (1911). Royal Commission on Coast Erosion. The Geographical Journal 38: 598601.Google Scholar
Özgüner, H. and Kendle, A. D. (2006). Public attitudes towards naturalistic versus designed landscapes in the city of Sheffield (UK), Landscape and Urban Planning 74: 139157.Google Scholar
Pacini, M., Pranzini, E., and Sirito, G. (1997). Beach nourishment with angular gravel at Cala Gonone (eastern Sardinia, Italy). In Proceedings of the Third International Conference on the Mediterranean Coastal Environment. Ankara: MEDCOAST Secretariat, pp. 10431058.Google Scholar
Packham, J. R., Randall, R. E., Barnes, R. S. K., and Neal, A. (Eds.). (2001). Ecology and Geomorphology of Coastal Shingle. Seattle: Westbury Academic & Scientific Publishing.Google Scholar
Pagán, J. I., López, M., López, I., Tenza-Abril, A. J., and Aragonés, L. (2018). Study of the evolution of gravel beaches nourished with sand. Science of the Total Environment 626: 8795.Google Scholar
Palmer, M. A., Ambrose, R. F., and Poff, N. L. (1997). Ecological theory and community restoration ecology. Restoration Ecology 5: 291300.Google Scholar
Pardini, E. A., Vickstrom, K. E., and Knight, T. M. (2015). Early successional microhabitats allow the persistence of endangered plants in coastal sand dunes. PLoS ONE 10(4): e0119567.Google Scholar
Parkinson, R. W. and Ogurcak, D. E. (2018). Beach nourishment is not a sustainable strategy to mitigate climate change. Estuarine, Coastal and Shelf Science 212: 203209.Google Scholar
Parrott, A. and Burningham, H. (2008). Opportunities of, and constraints to, the use of intertidal agri-environmental schemes for sustainable coastal defence: a case study of the Blackwater Estuary, southeast England. Ocean & Coastal Management 51: 352367.Google Scholar
Parsons, L. S., Sayre, J., Ender, C., Rodrigues, J. L., and Barberán, A. (2020). Soil microbial communities in restored and unrestored dune ecosystems in California. Restoration Ecology 28(S4): 311321.Google Scholar
Parsons, R. (1995). Conflict between ecological sustainability and environmental aesthetics: conundrum, canard or curiosity. Landscape and Urban Planning 32: 227244.Google Scholar
Parsons, R. and Daniel, T. C. (2002). Good looking: in defense of scenic landscape aesthetics. Landscape and Urban Planning 60: 4356.Google Scholar
Penland, S., Connor, P. F. Jr., Beall, A., Fearnley, S., and Williams, S. J. (2005). Changes in Louisiana’s shoreline: 1855–2002. Journal of Coastal Research SI44: 739.Google Scholar
Pérez-Hernández, E., Ferrer-Valero, N., and Hernández-Calvento, L. (2020). Lost and preserved coastal landforms after urban growth. The case of Las Palmas de Gran Canaria city (Canary Islands, Spain). Journal of Coastal Conservation 24: 26.Google Scholar
Pérez-Maqueo, O., Martínez, M. L., Lithgow, D., Mendoza-González, G., Feagin, R. A., and Gallego-Fernández, J. B. (2014). The coasts and their costs. In Martínez, M. L., Gallego-Fernández, J. B., and Hesp, P. A. (Eds.), Restoration of Coastal Dunes. New York: Springer, pp. 289304.Google Scholar
Peterson, C. H. and Bishop, M. L. (2005). Assessing the environmental impacts of beach nourishment. BioScience 55: 887896.Google Scholar
Peterson, C. H. and Lipcius, R. N. (2003). Conceptual progress towards predicting quantitative ecosystem benefits of ecological restorations. Marine Ecology Progress Series 264: 297307.Google Scholar
Peterson, C. H., Hickerson, D. H. M., and Johnson, G. G. (2000). Short-term consequences of nourishment and bulldozing on the dominant large invertebrates of a sandy beach. Journal of Coastal Research 16: 368378.Google Scholar
Peterson, C. H., Kneib, R. T., and Manen, C.-A. (2003). Scaling restoration actions in the marine environment to meet quantitative targets of enhanced ecosystem services. Marine Ecology Progress Series 264: 173175.Google Scholar
Peterson, C. H., Bishop, M. J., D’Anna, L. M., and Johnson, G. A. (2014). Multi-year persistence of beach habitat degradation from nourishment using coarse shelly sediments. Science of the Total Environment 487: 481492.Google Scholar
Pethick, J. (1996). The sustainable use of coasts: monitoring, modelling and management. In Jones, P. S., Healy, M. G., and Williams, A. T. (Eds.), Studies in European Coastal Management. Cardigan: Samara Publishing Ltd., 8392.Google Scholar
Pethick, J. (2001). The Anglian coast. In Bodungen, B. V. and Turner, R. K. (Eds.), Science and Integrated Coastal Management. Berlin: Dahlem University Press, pp. 121133.Google Scholar
Pezzuto, P. R., Resgalla, C. Jr., Abreu, J. G. N., and Menezes, J. T. (2006). Environmental impacts of the nourishment of Balneário Camboriú beach, SC, Brazil. Journal of Coastal Research SI39: 863868.Google Scholar
Phillips, M. R. (2009). Beach consequences of an industrial heritage. In Williams, A. and Micallef, A. (Eds.), Beach Management: Principles & Practice. London: Earthscan, pp. 359368.Google Scholar
Pickart, A. J. (2013). Dune restoration over two decades at the Lanphere and Ma-le’l dunes in northern California. In Martínez, M. L., Gallego-Fernández, J. B., and Hesp, P. A. (Eds.), Restoration of Coastal Dunes. New York: Springer, pp. 159185.Google Scholar
Pilkey, O. H. (1981). Geologists, engineers, and a rising sea level. Northeastern Geology 3/4: 150158.Google Scholar
Pilkey, O. H. (1992). Another view of beachfill performance. Shore and Beach 60(2): 2025.Google Scholar
Pilkey, O. H. Jr. and Cooper, J. A. G. (2012). “Alternative” shoreline erosion control devices: a review. In Cooper, J. A. G. and Pilkey, O. H. Jr. (Eds.), Pitfalls of Shoreline Stabilization: Selected Case Studies. Dordrecht: Springer Science+Business Media, pp. 187214.Google Scholar
Pilkey, O. H. and Wright, H. L. III (1988). Seawalls versus beaches. Journal of Coastal Research SI4: 4164.Google Scholar
Pinsky, M. L., Guannel, G., and Arkema, K. K. (2013). Quantifying wave attenuation to inform coastal habitat conservation. Ecosphere 4: 95.Google Scholar
Pinto, C., Silovsky, E., Henley, F., Rich, L., Parcell, J., and Boyer, D. (1972). The Oregon Dunes NPA Resource Inventory. Portland, OR: U.S. Department of Agriculture, Forest Service, Pacific Northwest Region.Google Scholar
Pinto, C. A., Silveira, T. M., and Teixeira, S. B. (2020). Beach nourishment practice in mainland Portugal (1950–2017): overview and retrospective. Ocean & Coastal Management 192: 105211.Google Scholar
Piotrowska, H. (1989). Natural and anthropogenic changes in sand dunes and their vegetation on the southern Baltic coast. In van der Meulen, F., Jungerius, P. D., and Visser, J. H. (Eds.), Perspectives in Coastal Dune Management. The Hague: SPB Academic Publishing, pp. 3340.Google Scholar
Plassmann, K., Laurence, M., Jones, M., and Edwards-Jones, G. (2010). Effects of long-term grazing management on sand dune vegetation of high conservation interest. Applied Vegetation Science 13: 100112.Google Scholar
Platt, R. H., Salvesen, D., and Baldwin, G.H. II (2002). Rebuilding the North Carolina coast after Hurricane Fran: did public regulations matter. Coastal Management 30: 249269.Google Scholar
Pluis, J. L. A. and de Winder, B. (1990). Natural stabilization. Catena Supplement 18: 195208.Google Scholar
Polomé, P., Marzetti, S., and van der Veen, A. (2005). Economic and social demands for coastal protection. Coastal Engineering 52: 819840.Google Scholar
Pontee, N. and Tarrant, O. (2017). Promoting coastal resilience using green infrastructure. Maritime Engineering 170: 3738.Google Scholar
Pontee, N. I., Pye, K., and Blott, S. J. (2004). Morphodynamic behaviour and sedimentary variation of mixed sand and gravel beaches, Suffolk, U.K. Journal of Coastal Research 20: 256276.Google Scholar
Portz, L., Manzolli, R. P., Hermanns, L., and Alcántara-Carrió, J. (2015). Evaluation of the efficiency of dune reconstruction techniques in Xangri-lá (Rio Grande do Sul, Brazil). Ocean & Coastal Management 104: 7889.Google Scholar
Portz, L., Manzolli, R. P., and Alcántara-Carrió, J. (2018). Dune system restoration in Osório municipality (Rio Grande do Sul, Brazil): good practices based on coastal management legislation. In Botero, C. M., Cervantes, O., and Finkl, C. W. (Eds.), Beach Management Tools – Concepts, Methodologies and Case Studies. Cham, Switzerland: Springer International Publishing, pp. 4158.Google Scholar
Posey, M. and Alphin, T. (2002). Resilience and stability in an offshore benthic community: responses to sediment borrow activities and hurricane disturbance. Journal of Coastal Research 18: 685697.Google Scholar
Powell, E. J., Tyrrell, M., Milliken, A., Tirpak, J. M., and Stoudinger, M. D. (2019). A review of coastal management approaches to support the integration of ecological and human community planning for climate change. Journal of Coastal Conservation 23: 118.Google Scholar
Powell, K. A. (1992). Engineering with conservation issues in mind. In Barrett, M. G. (Ed.), Coastal Zone Planning and Management. London: Thomas Telford, pp. 237249.Google Scholar
Pranzini, E. (2001). Updrift river mouth migration on cuspate deltas: two examples from the coast of Tuscany, Italy. Geomorphology 38: 125132.Google Scholar
Pranzini, E. (2009). Protection projects at Poetto and Cala Gonone beaches (Sardinia, Italy). In Williams, A. and Micallef, A. (Eds.), Beach Management: Principles & Practice. London: Earthscan, pp. 287306.Google Scholar
Pranzini, E. (2013). Italy. In Pranzini, E. and Williams, A. (Eds.), Coastal Erosion and Protection in Europe. London, Routledge, pp. 294323.Google Scholar
Pranzini, E. and Vitale, G. (2011). Beach sand colour: the need for a standardised assessment procedure. Journal of Coastal Research SI61: 6669.Google Scholar
Pranzini, E., Simonetti, D., and Vitale, G. (2010). Sand colour rating and chromatic compatibility of borrow sediments. Journal of Coastal Research 26: 798808.Google Scholar
Pranzini, E., Anfuso, G., Boteo, C.-M., et al. (2016). Sand color at Cuba and its influence on beach nourishment and management. Ocean & Coastal Management 126: 5160.Google Scholar
Pranzini, E., Anfuso, G., and Boteo, C. M. (2018a). Nourishing tourist beaches. In Botero, C. M., Cervantes, O., and Finkl, C. W. (Eds.), Beach Management Tools – Concepts, Methodologies and Case Studies. Cham, Switzerland: Springer International Publishing, pp. 293317.Google Scholar
Pranzini, E., Rossi, L., Lami, G., Jackson, N. L., and Nordstrom, K. F. (2018b). Reshaping beach morphology by modifying offshore breakwaters. Ocean & Coastal Management 154: 168177.Google Scholar
Prati, G., Albanesi, C., Pietrantoni, L., and Airoldi, L. (2016). Public perceptions of beach nourishment and conflict management strategies: a case study of Portonovo Bay in the Adriatic Italian coast. Land Use Policy 50: 422428.Google Scholar
Priskin, J. (2003). Physical impacts of four-wheel drive related tourism and recreation in a semi-arid, natural coastal environment. Ocean & Coastal Management 46: 127155.Google Scholar
Provoost, S., Laurence, M., Jones, M., and Edmondson, S. E. (2011). Changes in landscape and vegetation of coastal dunes in northwest Europe: a review. Journal of Coastal Conservation 15: 207226.Google Scholar
Psuty, N. P. and Moreira, M. E. S. A. (1992). Characteristics and longevity of beach nourishment at Praja da Rocha, Portugal. Journal of Coastal Research SI8: 660676.Google Scholar
Psuty, N. P. and Silveira, T. M. (2010). Global climate change: an opportunity for coastal dunes? Journal of Coastal Conservation 14: 153160.Google Scholar
Purvis, K. G., Gramling, J. M., and Murren, C. J. (2015). Assessment of beach access paths on dune vegetation: diversity, abundance and cover. Journal of Coastal Research 31: 12221228.Google Scholar
Pye, K. and Blott, S. J. (2015). Spatial and temporal variations in soft-cliff erosion along the Holderness coast, East Riding of Yorkshire, UK. Journal of Coastal Conservation 19: 785808.Google Scholar
Pye, K. and Blott, S. J. (2016). Dune rejuvenation Trials Overview Report. Natural Resources Wales Evidence Report No. 296, Natural Resources Wales, Bangor.Google Scholar
Pye, K. and Blott, S. J. (2017). Evolution of a sediment-starved, over-stabilized dunefield: Kenfig Burrows, South Wales, UK. Journal of Coastal Conservation 21: 685717.Google Scholar
Pye, K. and Blott, S. J. (2020). Is “re-mobilisation” nature restoration or nature destruction? A commentary. Discussion. Journal of Coastal Conservation 24: 10.Google Scholar
Pye, K., Blott, S. J., and Howe, M. A. (2014). Coastal dune stabilization in Wales and requirements for rejuvenation. Journal of Coastal Conservation 18: 2754.Google Scholar
Rabenold, C. (2013). Coastal zone management: using no-build areas to protect the shorefront. Coastal Management 41: 294311.Google Scholar
Rai, P. K. and Kim, K.-H. (2020). Invasive alien plants and environmental remediation: a new paradigm for sustainable restoration ecology. Restoration Ecology 28: 37.Google Scholar
Rakocinski, C. F., Heard, R. W., LeCroy, S. E., McLelland, J. A., and Simons, T. (1996). Responses by macrobenthic assemblages to extensive beach restoration at Perdido Key, Florida, U.S.A. Journal of Coastal Research 12: 326353.Google Scholar
Randall, R. E. (1996). The shingle survey of Great Britain and its implications for conservation management. In Salman, A. H. P. M., Langeveld, M. J., and Bonazountas, M. (Eds.), Coastal Management and Habitat Conservation. Leiden: EUCC, pp. 369376.Google Scholar
Randall, R. E. (2004). Management of coastal vegetated shingle in the United Kingdom. Journal of Coastal Conservation 10: 159168.Google Scholar
Rankin, K. L., Bruno, M. S., and Herrington, T. O. (2004). Nearshore currents and sediment transport measured at notched groins. Journal of Coastal Research SI33: 237254.Google Scholar
Ranwell, D. S. (1972). Ecology of Salt Marshes and Sand Dunes. London: Chapman and Hall.Google Scholar
Ranwell, D. S. and Boar, R. (1986). Coast Dune Management Guide. Institute of Terrestrial Ecology, NERC.Google Scholar
Ratnayake, N. P., Ranayake, A. S., Azoor, R. M., et al. (2019). Erosion processes driven by monsoon events after a beach nourishment and breakwater construction at Uswetakeiyawa Beach, Sri Lanka SN Applied Sciences 1: 52.Google Scholar
Redi, B. H., van Aarde, R. J., and Wassenaar, T. D. (2005). Coastal dune forest development and the regeneration of millipede communities. Restoration Ecology 13: 284291.Google Scholar
Rees, S., Curson, J., and Evans, D. (2015). Conservation of soft cliffs in England 2002–2013. Journal of Coastal Conservation 19: 761769.Google Scholar
Reid, J., Santana, G. G., Klein, A. H. F., and Diehl, F. L. (2005). Perceived and realized social and economic impacts of sand nourishment at Piçarras Beach, Santa Catarina, Brazil. Shore and Beach 73(4): 1418.Google Scholar
Reilly, F. J. and Bellis, V. J. (1983). The Ecological Impact of Beach Nourishment with Dredged Materials on the Intertidal Zone at Bogue Banks, North Carolina. Miscellaneous Report 83-3. Ft. Belvoir, VA: U.S. Army Corps of Engineers, Coastal Engineering Research Center.Google Scholar
Reinicke, R. (2001). Inseln der Ostsee: Landschaften und Naturschönheit. Bremen: Giritz & Gottschalk.Google Scholar
Rhind, P. M. and Jones, P. S. (1999). The floristics and conservation status of sand-dune communities in Wales. Journal of Coastal Conservation 5: 3142.Google Scholar
Rhind, P. and Jones, R. (2009). A framework for the management of sand dune systems in Wales. Journal of Coastal Conservation 13: 1523.Google Scholar
Rhind, P., Jones, R., and Jones, L. (2013). The impact of dune stabilization on the conservation status of sand dune systems in Wales. In Martínez, M. L., Gallego-Fernández, J. B., and Hesp, P. A. (Eds.), Restoration of Coastal Dunes. New York: Springer, pp. 125143.Google Scholar
Richards, E. G. and Burningham, H. (2011). Hippophae rhamnoides on a coastal dune system: a thorny issue? Journal of Coastal Conservation 15: 7385.Google Scholar
Riksen, M. J., Goossens, D., Huiskes, H. P., Krol, J., and Slim, P. A. (2016). Constructing notches in foredunes: effect on sediment dynamics in the dune hinterland, Geomorphology 253: 340352.Google Scholar
Risser, P. G. (1995). The status of the science examining ecotones. Bioscience 45: 318325.Google Scholar
Ritchie, W. and Gimingham, C. H. (1989). Restoration of coastal dunes breached by pipeline landfalls in northeast Scotland. Proceedings of the Royal Society of Edinburgh 96B: 231245.Google Scholar
Ritchie, W. and Penland, S. (1990). Aeolian sand bodies of the south Louisiana coast. In Nordstrom, K. F., Psuty, N. P., and Carter, R. W. G. (Eds.), Coastal Dunes: Form and Process. Chichester: John Wiley & Sons, pp. 105127.Google Scholar
Roberts, C. M. and Hawkins, J. P. (1999). Extinction risk in the sea. Trends in Ecology and Evolution 14: 241246.Google Scholar
Roberts, N. (1989). The Holocene: An Environmental History. New York: Basil Blackwell.Google Scholar
Roberts, T. M. and Wang, P. (2012). Four-year performance and associated controlling factors of several beach nourishment projects along three adjacent barrier islands, west-central Florida, USA. Coastal Engineering 70: 2139.Google Scholar
Robley, A., Purdey, D., Johnston, M., Lindeman, M., Busana, F., and Long, K. (2007). Experimental trials to determine effective fence designs for feral cat and fox exclusion. Ecological Management and Restoration 8: 193198.Google Scholar
Roca, E. and Villares, M. (2012). Public perceptions of managed realignment strategies: the case study of the Ebro Delta in the Mediterranean basin. Ocean & Coastal Management 60: 3847.Google Scholar
Roca, E. and Villares, M. (2018). Integrating social perceptions in beach management. In Botero, C. M., Cervantes, O., and Finkl, C. W. (Eds.), Beach Management Tools – Concepts, Methodologies and Case Studies. Cham, Switzerland: Springer International Publishing, pp. 875893.Google Scholar
Rodrigues, R. S., Mascarenhas, A., and Jagtap, T. G. (2011). An evaluation of flora from coastal sand dunes of India: Rationale for conservation and management. Ocean & Coastal Management 54: 181188.Google Scholar
Rodriguez, A. B., Fegley, S. R., Ridge, J. T., van Dusen, B. M., and Anderson, N. (2013). Contribution of aeolian sand to backbarrier marsh sedimentation. Estuarine, Coastal and Shelf Science 117: 248259.Google Scholar
Rogers, S. M. (1993). Relocating erosion-threatened buildings: a study of North Carolina housemoving. In Coastal Zone 93. New York: American Society of Civil Engineers, pp. 13921405.Google Scholar
Roman, C. T. and Nordstrom, K. F. (1988). The effect of erosion rate on vegetation patterns of an east coast barrier island. Estuarine, Coastal and Shelf Science 26: 233242.Google Scholar
Romano, B. and Zullo, F. (2014). The urban transformation of Italy’s Adriatic coastal strip: fifty years of unsustainability. Land Use Policy 38: 2636.Google Scholar
Ruessink, B. G., Arens, S. M., Kuipers, M., and Donker, J. J. A. (2018). Coastal dune dynamics in response to excavated foredune notches. Aeolian Research 31A: 317.Google Scholar
Rumbold, D. G., Davis, P. W., and Perretta, C. (2001). Estimating the effect of beach nourishment on Caretta caretta (loggerhead sea turtle) nesting. Restoration Ecology 9: 304310.Google Scholar
Runyan, K. and Griggs, G. B. (2003). The effects of armoring seacliffs on the natural sand supply to the beaches of California. Journal of Coastal Research 19: 336347.Google Scholar
Rupp-Armstrong, S. and Nicholls, R. J. (2007). Coastal and estuarine retreat: a comparison of the application of managed realignment in England and Germany. Journal of Coastal Research 23: 14181430.Google Scholar
Ruz, M.-H. and Anthony, E. J. (2008). Sand trapping by brushwood fences on a beach-foreshore contact: the primacy of the local sediment budget. Zeitschrift für Geomorphologie 52(Suppl. 3): 179194.Google Scholar
Saathoff, F., Oumeraci, H., and Restall, S. (2007). Australian and German experiences on the use of geotextile containers. Geotextiles and Geomembranes 25: 251263.Google Scholar
Saffir, H. S. (1991). Hurricane Hugo and implications for design professionals and code-writing authorities. Journal of Coastal Research SI8: 2532.Google Scholar
Salgado, K. and Martínez, M. L. (2017). Is ecosystem-based coastal defense a realistic alternative? Exploring the evidence. Journal of Coastal Conservation 21: 837848.Google Scholar
Salmon, J., Henningsen, D., and McAlpin, T. (1982). Dune Restoration and Vegetation Manual. SGR-48. Gainesville: Florida Sea Grant College Program.Google Scholar
Sancho-García, A., Guillén, J., and Ojeda, E. (2013). Storm-induced readjustment of an embayed beach after modification by protection works. Geo-Marine Letters 33: 159172.Google Scholar
Sanjaume, E. (1992). Valencia coast: human impact and dune conservation. Coastline 1: 1013.Google Scholar
Savard, J.-P. L., Clergeau, P., and Mennechez, G. (2000). Biodiversity concepts and urban ecosystems. Landscape and Urban Planning 43: 131142.Google Scholar
Schernewski, G., Schumacher, J., Weisner, E., and Donges, L. (2018). A combined coastal protection, realignment and wetland restoration scheme in the southern Baltic: planning process, public information and participation. Journal of Coastal Conservation 22: 533547.Google Scholar
Schlacher, T. A., Dugan, J., Schoeman, D. S., et al. (2006). Sandy beaches at the brink. Diversity and Distributions 13: 556560.Google Scholar
Schlacher, T. A., Noriega, R., Jones, A., and Dye, T. (2012). The effects of beach nourishment on benthic invertebrates in eastern Australia: impacts and variable recovery. Science of the Total Environment 435: 411417.Google Scholar
Schmahl, G. P. and Conklin, E. J. (1991). Beach erosion in Florida: a challenge for planning and management. In Coastal Zone 91. New York: American Society of Civil Engineers, pp. 261271.Google Scholar
Schooler, N. K., Dugan, J. E., and Hubbard, D. M. (2019). No lines in the sand: impacts of intense mechanized maintenance regimes on sandy beach ecosystems span the intertidal zone on urban coasts. Ecological Indicators 106: 105457.Google Scholar
Schreck Reis, C., Antunes do Carmo, J., and Freitas, H. (2008). Learning with nature: a sand dune system case study (Portugal). Journal of Coastal Research 26: 15061515.Google Scholar
Schulze-Dieckhoff, M. (1992). Propagating dune grasses by cultivation for dune conservation. In Carter, R. W. G., Curtis, T. G. F., and Sheehy-Skeffington, M. J. (Eds.), Coastal Dunes: Geomorphology, Ecology and Management for Conservation. Rotterdam: A.A. Balkema, pp. 361366.Google Scholar
Schupp, C. A., Winn, N. T., Pearl, T. L., Kumer, J. P., Carruthers, T. J. B., and Zimmerman, C. S. (2013). Restoration of overwash processes creates piping plover (Charadrius melodus) habitat on a barrier island (Assateague Island, Maryland). Estuarine, Coastal and Shelf Science 116: 1120.Google Scholar
Schwarzer, K., Crossland, C. J., De Luca Rebbello Wagener, A., et al. (2001). Group report: shoreline development. In Bodungen, B. V. and Turner, R. K. (Eds.), Science and Integrated Coastal Management. Berlin: Dahlem University Press, pp. 121133.Google Scholar
Schwendiman, J. L. (1977). Coastal sand dune stabilization in the Pacific Northwest. International Journal of Biometeorology 21: 281289.Google Scholar
Scyphers, S. B, Powers, S. P., Heck, K. L. Jr., and Byron, D. (2011). Oyster reefs as natural breakwaters mitigate shoreline loss and facilitate fisheries. PLoS ONE 6(8): e22396.Google Scholar
Scott, G. A. (1963). The ecology of shingle beach plants. Journal of Ecology 51: 517527.Google Scholar
Sea Isle City. (1982). Sea Isle City Centennial 1882–1982. Sea Isle City, NJ: City Hall.Google Scholar
Seabloom, E. W. and Wiedemann, A. M. (1994). Distribution and effects of Ammophila breviligulata Fern. (American beachgrass) on the foredunes of the Washington coast. Journal of Coastal Research 10: 178188.Google Scholar
Seltz, J. (1976). The Dune Book: How to Plant Grasses for Dune Stabilization. UNC-SG-76-16. Raleigh: North Carolina University Sea Grant.Google Scholar
Seymour, A. C., Ridge, J. T., Rodriquez, A. B., Newton, E., Dale, J., and Johnston, D. W. (2017). Deploying fixed wing unoccupied aerial systems (UAS) for coastal morphology assessment and management. Journal of Coastal Research 34: 704717.Google Scholar
Sharp, W. C. and Hawk, V. B. (1977). Establishment of woody plants for secondary and tertiary dune stabilization along the mid-Atlantic coast. International Journal of Biometeorology 21: 245255.Google Scholar
Sheik Mujabar, P. and Chandrasekar, N. (2013). Coastal erosion hazard and vulnerability assessment for southern coastal Tamil Nadu of India by using remote sensing and GIS. Natural Hazards 69: 12951314.Google Scholar
Sherman, D. J. (1995). Problems of scale in the modeling and interpretation of coastal dunes. Marine Geology 124: 339349.Google Scholar
Sherman, D. J. and Nordstrom, K. F. (1994). Hazards of wind blown sand and sand drift. Journal of Coastal Research SI12: 263275.Google Scholar
Shibutani, Y., Kuroiwa, M., and Matsubara, Y. (2016). Effect of coastal protection using the beach nourishment at Tottori sand dune coast. Journal of Coastal Research SI75: 695699.Google Scholar
Shipman, H. (2001). Beach nourishment on Puget Sound: a review of existing projects and potential applications. In Puget Sound Research 2001. Olympia, WA: Puget Sound Water Quality Action Team, pp. 18.Google Scholar
Shipman, H., Stoops, K., and Hummel, P. (2000). Seattle Waterfront Parks: Applications of Beach Nourishment. Seattle: Washington Coastal Planner’s Group.Google Scholar
Shipman, H., Dethier, M. N., Gelfenbaum, G., Fresh, K. L., and Dinicola, R. S. (Eds.). (2010). Puget Sound Shorelines and the Impacts of Armoring. Reston, VA: U.S. Geological Survey.Google Scholar
Shu, F., Cai, F., Qi, H., Liu, J., Lei, G., and Zheng, J. (2019). Morphodynamics of an artificial cobble beach in Tianquan Bay, Xiamen, China. Journal of Ocean University of China 18: 868882.Google Scholar
Shuisky, Y. D. and Schwartz, M. L. (1988). Human impact and rates of shoreline retreat along the Black Sea coast. Journal of Coastal Research 4: 405416.Google Scholar
Siddle, R. P., Rowe, S., and Moore, R. (2016). Adaptation to coastal cliff instability and erosion and property loss: case study into the Knipe Point cliff retreat Pathfinder Project. In Baptiste, A. (Ed.), Coastal Management: Changing Coast, Changing Climate, Changing Minds. International Coastal Management Conference. London: ICE Publishing, pp. 163172.Google Scholar
Sigren, J. M., Figlus, J., Highfield, W., Feagin, R. A., and Armitage, A. R. (2018). The effects of coastal dune volume and vegetation on storm-induced property damage: analysis from Hurricane Ike. Journal of Coastal Research 34: 164173.Google Scholar
Silva, R., Martínez, M. L., Odériz, I., Mendoza, E., and Feagin, R. A. (2016). Response of vegetated dune-beach systems to storm conditions. Coastal Engineering 109: 5362.Google Scholar
Silveira, T. M., Franzão Santos, C., and Andrade, F. (2013). Beneficial use of dredged sand for beach nourishment and coastal landform enhancement – the case study of Tróia, Portugal. Journal of Coastal Conservation 17: 825832.Google Scholar
Simeoni, U., Calderoni, G., Tessari, U., and Mazzini, E. (1999). A new application of system theory to foredunes intervention strategy. Journal of Coastal Research 15: 457470.Google Scholar
Simpson, T. B. (2005). Ecological restoration and re-understanding ecological time. Ecological Restoration 23: 4651.Google Scholar
Skaradek, W., Miller, C., and Hocker, P. (2003). Beachgrass Planting Guide for Municipalities and Volunteers. Cape May Plant Materials Center, U.S. Department of Agriculture Natural Resources Conservation Service.Google Scholar
Skarregaard, P. (1989). Stabilisation of coastal dunes in Denmark. In van der Meulen, F., Jungerius, P. D., and Visser, J. H. (Eds.), Perspectives in Coastal Dune Management. The Hague: SPB Academic Publishing, pp. 151161.Google Scholar
Slott, J. M., Murray, A. B., and Ashton, A. D. (2010). Large-scale responses of complex-shaped coastlines to local shoreline stabilization and climate change. Journal of Geophysical Research 115: F03033.Google Scholar
Smallegan, S. M., Irish, J. L., van Dongeren, A. R., and Den Bieman, J. P. (2016). Morphological response of a sandy barrier island with a buried seawall during Hurricane Sandy. Coastal Engineering 110: 102110.Google Scholar
Smith, G. and Mocke, G. P. (1998). Coastline evolution in response to a major mine sediment discharge on the Namibian coastline. In Coastal Engineering. Reston, VA: American Society of Civil Engineers, pp. 26962709.Google Scholar
Smith, G., Mocke, G. P., van Ballegooyen, R., and Soltau, C. (2002). Consequences of sediment discharge from dune mining at Elizabeth Bay, Namibia. Journal of Coastal Research 18: 776791.Google Scholar
Smith, J. A. M., Niles, L. J., Hafner, S., Modjeski, A., and Dillingham, T. (2020). Beach restoration improves habitat quality for American horseshoe crabs and shorebirds in the Delawar Bay, USA. Marine Ecology Progress Series 645: 91107.Google Scholar
Smith, K. J. (1991). Beach politics – the importance of informed, local support for beach restoration projects. In Coastal Zone 91. New York: American Society of Civil Engineers, pp. 5661.Google Scholar
Smith, R. A. (1992). Conflicting trends of beach resort development: a Malaysian case. Coastal Management 20: 167187.Google Scholar
Smyth, T. A. G. and Hesp, P. A. (2015). Aeolian dynamics of beach scraped ridge and dyke structures. Coastal Engineering 99: 3845.Google Scholar
Snyder, M. R. and Pinet, P. R. (1981). Dune construction using two multiple sand-fence configurations: implications regarding protection of eastern Long Island’s south shore. Northeastern Geology 3: 225229.Google Scholar
Snyder, R. A. and Boss, C. L. (2002). Recovery and stability in barrier island plant communities. Journal of Coastal Research 18: 530536.Google Scholar
Soares, A. G., Scapini, F., Brown, A. C., and McLachlan, A. (1999). Phenotypic plasticity, genetic similarity and evolutionary inertia in changing environments. The Malacological Society of London 65: 136139.Google Scholar
Society for Ecological Restoration. (2002). The SER Primer on Ecological Restoration. www.ser.org/.Google Scholar
Somerville, S. E., Miller, K. L., and Mair, J. M. (2003). Assessment of the aesthetic quality of a selection of beaches in the Firth of Forth, Scotland. Marine Pollution Bulletin 46: 11841190.Google Scholar
Soulsby, C., Hannah, D., Malcolm, R., Maizels, J. K., and Gard, R. (1997). Hydrogeology of a restored coastal dune system in northeastern Scotland. Journal of Coastal Conservation 3: 143154.Google Scholar
Sparks, P. R. (1991). Wind conditions in Hurricane Hugo and their effect on buildings in South Carolina. Journal of Coastal Research SI8: 1324.Google Scholar
Speybroeck, J., Bonte, D., Courtens, W., et al. (2006). Beach nourishment: an ecologically sound coastal defence alternative? A review. Aquatic Conservation: Marine and Freshwater Ecosystems 16: 419435.Google Scholar
Spodar, A., Héquette, A., Ruz, M.-H., et al. (2018). Evolution of a beach nourishment project using dredged sand from navigation channel, Dunkirk, northern France. Journal of Coastal Conservation 22: 457474.Google Scholar
Stallins, J. A. and Corenblit, D. (2018). Interdependence of geomorphic and ecologic resilience properties in a geographic context. Geomorphology 305: 7693.Google Scholar
Starkes, J. (2001). Reconnaissance Assessment of the State of the Nearshore Ecosystem: Eastern Shore of Central Puget Sound, Including Vashon and Maury Islands (WRIAS 8 and 9). Seattle: King County Department of Natural Resources.Google Scholar
Stauble, D. K. and Nelson, W. G. (1985). Guidelines for beach nourishment: a necessity for project management. In Coastal Zone 85. New York: American Society of Civil Engineers, pp. 10021021.Google Scholar
Stein, E. D., Doughty, C. L., Lowe, J., Cooper, M., Sloane, E. B., and Liza, D. (2020). Establishing targets for regional coastal wetland restoration planning using historical ecology and future scenario analysis: the past, present, future approach. Estuaties and Coasts 43: 207222.Google Scholar
Steinitz, M. J., Salmon, M., and Wyneken, J. (1998). Beach renourishment and loggerhead turtle reproduction: a seven year study at Jupiter Island, Florida. Journal of Coastal Research 14: 10001013.Google Scholar
Stive, M. J. F., de Schipper, M. A., Luijendijk, A. P., et al. (2013). A new alternative to saving our beaches from sea-level rise: the Sand Engine. Journal of Coastal Research 29: 10011008.Google Scholar
Stocker, L. and Kennedy, D. (2009). Cultural models of the coast in Australia: toward sustainability. Coastal Management 37: 387404.Google Scholar
Stocker, T. F., Qin, D., Plattner, G.-K., et al. (Eds.). (2013). IPCC, 2013: Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge: Cambridge University Press.Google Scholar
Stratford, C. and Rooney, P. (2017). Special issue – coastal dune slack hydro-ecology. Journal of Coastal Conservation 21: 573576.Google Scholar
Stratford, C. J., Robins, N. S., Clarke, D., Jones, L., and Weaver, G. (2013). An ecohydrological review of dune slacks on the west coast of England and Wales. Ecohydrology 6: 162171.Google Scholar
Stull, K. J., Cahoon, L. B., and Lankford, T. E. (2016). Zooplankton abundance in the surf zones of nourished and unnourished beaches in southeastern North Carolina, U.S.A. Journal of Coastal Research 32: 7077.Google Scholar
Sturgess, P. (1992). Clear-felling dune plantations: studies in vegetation recovery. In Carter, R. W. G., Curtis, T. G. F., and Sheehy-Skeffington, M. J. (Eds.), Coastal Dunes: Geomorphology, Ecology and Management for Conservation. Rotterdam: A.A. Balkema, pp. 339349.Google Scholar
Sturgess, P. and Atkinson, D. (1993). The clear-felling of sand dune plantations: soil and vegetational processes in habitat restoration. Biological Conservation 66: 171183.Google Scholar
Sutton-Grier, A. E., Wowk, K., and Bamford, H. (2015). Future of our coasts: the potential for natural and hybrid infrastructure to enhance the resilience of our coastal communities, economies and ecosystems. Environmental Science and Policy 51: 137148.Google Scholar
Swart, J. A. A., van der Windt, H. J., and Keulartz, J. (2001). Valuation of nature in conservation and restoration. Restoration Ecology 9: 230238.Google Scholar
Taylor, E. B., Gibeaut, J. C., Yoskowitz, D. W., and Starek, M. J. (2015). Assessment and monetary valuation of the storm protection function of beaches and foredunes on the Texas coast. Journal of Coastal Research 31: 12051216.Google Scholar
Taylor, R. B. and Frobel, D. (1990). Approaches and results of a coastal dune restoration program on Sable Island, Nova Scotia. In Davidson-Arnott, R. G. D. (Ed.), Proceedings of the Symposium on Coastal Sand Dunes. Ottawa: National Research Council Canada, pp. 405431.Google Scholar
Teixeira, L. H., Weisser, W., and Ganade, G. (2016). Facilitation and sand burial effect plant survival during restoration of a tropical coastal sand dune degraded by tourist carsRestoration Ecology 24390397.Google Scholar
Télez-Duarte, M. A. (1993). Cultural resources as a criterion in coastal zone management: the case of northwestern Baja California, Mexico. In Fermán-Almada, J. L., Gómez-Morin, L., and Fischer, D. W. (Eds.), Coastal Zone Management in Mexico: The Baja California Experience. New York: American Society of Civil Engineers, pp. 137147.Google Scholar
Thieler, R. E., Pilkey, O. H. Jr., Young, R. S., Bush, D. M., and Chai, F. (2000). The use of mathematical models to predict beach behavior for U.S. coastal engineering: a critical review. Journal of Coastal Research 16: 4870.Google Scholar
Throop, W. and Purdom, R. (2006). Wilderness restoration: the paradox of public participation. Restoration Ecology 14: 493499.Google Scholar
Tinley, K. L. (1995). Coastal Dunes of South Africa. South African National Scientific Programmes Report No. 109.Google Scholar
Titus, J. G. (1990). Greenhouse effect, sea level rise, and barrier islands: case study of Long Beach Island, New Jersey. Coastal Management 18: 6590.Google Scholar
Toft, J. D., Cordell, J. R., Heerhartz, S. M., Armbrust, E. A., and Simenstad, C. A. (2010). Fish and invertebrate response to shoreline armoring and restoration in Puget Sound. In Shipman, H., Dethier, M. N., Gelfenbaum, G., Fresh, K. L., and Dinicola, R. S. (Eds.), Puget Sound Shorelines and the Impacts of Armoring. Reston, VA: U.S. Geological Survey, pp. 161170.Google Scholar
Toft, J. D., Ogston, A. S., Heerhartz, S. M., Cordell, J. R., and Flemer, E. E. (2013). Ecological response and physical stability of habitat enhancements along an urban armored shoreline. Ecological Engineering 57: 97108.Google Scholar
Toimil, A., Losada, I. J., Nicholls, R. J., Dalrymple, R. A., and Stive, M. J. F. (2020). Addressing the challenges of climate change risks and adaptation in coastal areas: a review. Coastal Engineering 156: 103611.Google Scholar
Tomasicchio, U. (1996). Submerged breakwaters for the defence of the shoreline at Ostia: field experiences, comparison. In Proceedings of the 25th International Conference on Coastal Engineering. New York: American Society of Civil Engineers, pp. 24042417.Google Scholar
Tondeur, Y., Vining, B., Mace, K., Mills, W., and Hart, J. (2012). Environmental release of dioxins from reservoir sources during beach nourishment programs. Chemosphere 88: 358363.Google Scholar
Tonnen, P. K., Huisman, B. J. A., Stam, G. N., and van Rijn, L. C. (2018). Numerical modeling of erosion rates, life span and maintenance volumes of mega nourishments. Coastal Engineering 131: 5169.Google Scholar
Townend, I. H. and Fleming, C. A. (1991). Beach nourishment and socio-economic aspects. Coastal Engineering 16: 115127.Google Scholar
Trembanis, A. C. and Pilkey, O. H. (1998). Summary of beach nourishment along the U.S. Gulf of Mexico shoreline. Journal of Coastal Research 14: 407417.Google Scholar
Tresca, A., Ruz, M.-H., and Grégoire, P. (2014). Coastal dune development and sand drifting management along and artificial shoreline: the case of Dunkirk harbor, northern France. Journal of Coastal Conservation 18: 495504.Google Scholar
Tudor, D. T. and Willams, A. T. (2003). Public perception and opinion of visible beach aesthetic pollution: the utilisation of photography. Journal of Coastal Research 19: 11041115.Google Scholar
Tukiainen, H., Kiuttu, M., Kalliola, R., Alahuhta, J., and Hjort, J. (2019). Landforms contribute to plant biodiversity at alpha, beta and gamma levels. Journal of Biogeography 46: 16991710.Google Scholar
Tunstall, S. M. and Penning-Rowsell, E. C. (1998). The English beach: experiences and values. The Geographical Journal 164: 319332.Google Scholar
Turkenli, T. S. (2005). Human activity in landscape seasonality: the case of tourism in Crete. Landscape Research 30: 221239.Google Scholar
Turnhout, E., Hisschemöller, M., and Eijsackers, H. (2004). The role of views of nature in Dutch nature conservation: the case of the creation of a drift sand area in the Hoge Veluwe National Park. Environmental Values 13: 187198.Google Scholar
Tye, R. S. (1983). Impact of Hurricane David and mechanical dune restoration on Folly Beach, South Carolina. Shore and Beach 51(2): 39.Google Scholar
U.S. Army Corps of Engineers. (1980). Beach Erosion Control Colonial Beach, Virginia: Detailed Project Report. Baltimore: U.S. Army Corps of Engineers.Google Scholar
U.S. Army Corps of Engineers. (1986). Lincoln Park Shoreline Erosion Control Seattle Washington: Final Detailed Project Report and Final Environmental Assessment. Seattle: U.S. Army Corps of Engineers.Google Scholar
US Army Corps of Engineers. (2001). The New York District’s Biological Monitoring Program for the Atlantic Coast of New Jersey, Asbury Park to Manasquan Section Beach Erosion Control Project. Vicksburg, MS: Engineer Research and Development Center, Waterways Experiment Station.Google Scholar
U.S. Fish and Wildlife Service. (2002). Draft Fish and Wildlife Coordination Act Report: Bogue Banks Shore Protection Project, Carteret County, NC. Raleigh, NC: Raleigh Ecological Services Field Office, U.S. Fish and Wildlife Service.Google Scholar
Utizi, K., Corbau, C., Rodella, I., Nannini, S., and Simeoni, U. (2016). A mixed solution or a highly protected coast (Punta Marina, Northern Adriatic Sea, Italy). Marine Geology 381: 114127.Google Scholar
Valiela, I., Peckol, P., D’Avanzo, C., et al. (1998). Ecological effects of major storms on coastal watersheds and coastal waters: Hurricane Bob on Cape Cod. Journal of Coastal Research 14: 218238.Google Scholar
Valverde, H. R., Trembanis, A. C., and Pilkey, O. H. (1999). Summary of beach nourishment episodes on the U.S. east coast barrier islands. Journal of Coastal Research 15: 11001118.Google Scholar
van Aarde, R. J., Wassenaar, T. D., Niemand, L., Knowles, T., and Ferreira, S. (2004). Coastal dune forest rehabilitation: a case study on rodent and bird assemblages in northern Kwazulu-Natal, South Africa. In Martínez, M. L. and Psuty, N. P. (Eds.), Coastal Dunes, Ecology and Conservation. Berlin: Springer-Verlag, pp. 103115.Google Scholar
van Bohemen, H. D., and Meesters, H. J. N. (1992). Ecological engineering and coastal defense. In Carter, R. W. G., Curtis, T. G. F., and Sheehy-Skeffington, M. J. (Eds.), Coastal Dunes: Geomorphology, Ecology and Management for Conservation. Rotterdam: A.A. Balkema, pp. 369378.Google Scholar
van Boxel, J. H., Jungerius, P. D., Kieffer, N., and Hampele, N. (1997). Ecological effects of reactivation of artificially stabilized blowouts in coastal dunes. Journal of Coastal Conservation 3: 5762.Google Scholar
van den Hoek, R. E., Brugnach, M., and Hoekstra, A. Y. (2012). Shifting to ecological engineering in flood management: introducing new uncertainties in the development of a Building with Nature pilot project. Environmental Science and Policy 22: 8599.Google Scholar
van der Biest, K., de Nocker, L., Povoost, S., Boerema, A., Staes, J., and Meire, P. (2017). Dune dynamics safeguard ecosystem services. Ocean & Coastal Management 149: 148158.Google Scholar
van der Biest, K., Meire, P., Schellekens, T., et al. (2020). Aligning biodiversity conservation and ecosystem services in spatial planning: focus on ecosystem processes. Science of the Total Environment 712: 136350.Google Scholar
van der Hagen, H. G. J. M., Geelen, L. H. W. T., and de Vries, C. N. (2008). Dune slack restoration in Dutch mainland coastal dunes. Journal for Nature Conservation 16: 111.Google Scholar
van der Laan, D., van Tongeren, O. F. R., van der Putten, W. H., and Veenbaas, G. (1997). Vegetation development in coastal foredunes in relation to methods of establishing marram grass (Ammophila arenaria). Journal of Coastal Conservation 3: 179190.Google Scholar
van der Maarel, E. (1979). Environmental management of coastal dunes in The Netherlands. In Jefferies, R. L. and Davy, A. J. (Eds.), Ecological Processes in Coastal Environments. Oxford: Blackwell, pp. 543570.Google Scholar
van der Merwe, D., and McLachlan, A. (1991). The interstitial environment of coastal dune slacks. Journal of Arid Environments 21: 151163.Google Scholar
van der Meulen, F. and Salman, A. H. P. M. (1995). Management of Mediterranean coastal dunes. In Salman, A. H. P. M., Berends, H., and Bonazountas, M. (Eds.), Coastal Management and Habitat Conservation. Leiden: EUCC, pp. 261277.Google Scholar
van der Meulen, F. and Salman, A. H. P. M. (1996). Management of Mediterranean coastal dunes. Ocean & Coastal Management 30: 177195.Google Scholar
van der Meulen, F., Bakker, T. W. M., and Houston, J. A. (2004). The costs of our coasts: examples of dynamic dune management from western Europe. In Martínez, M. L. and Psuty, N. P. (Eds.), Coastal Dunes, Ecology and Conservation. Berlin: Springer-Verlag, pp. 259277.Google Scholar
van der Meulen, F., van der Valk, B., Baars, L., Schoor, E., and van Woerden, H. (2014). Development of new dunes in the Dutch Delta: nature compensation and “building with nature”. Journal of Coastal Conservation 18: 505513.Google Scholar
van der Meulen, F., van der Valk, B., Vertegaal, K., and van Eerden, M. (2015). “Building with nature” at the Dutch dune coast: compensation target management in Spanjaard Duin at EU and regional policy levels. Journal of Coastal Conservation 19: 707714.Google Scholar
van der Putten, W. H. (1990). Establishment and management of Ammophila arenaria (marram grass) on artificial coastal foredunes in The Netherlands. In Davidson-Arnott, R. G. D. (Ed.), Proceedings of the Symposium on Coastal Sand Dunes. Ottawa: National Research Council Canada, pp. 367387.Google Scholar
van der Putten, W. H. and Kloosterman, E. H. (1991). Large-scale establishment of Ammophila arenaria and quantitative assessment by remote sensing. Journal of Coastal Research 7: 11811194.Google Scholar
van der Putten, W. H. and Peters, B. A. M. (1995). Possibilities for management of coastal foredunes with deteriorated stands of Ammophila arenaria (marram grass). Journal of Coastal Conservation 1: 2939.Google Scholar
Van der Salm, J. and Unal, O. (2003). Towards a common Mediterranean framework for beach nourishment projects Journal of Coastal Conservation 9: 3542.Google Scholar
van der Veen, A., Grootjans, A. P., de Jong, J., and Rozema, J. (1997). Reconstruction of an interrupted primary beach plain succession using a geographical information system. Journal of Coastal Conservation 3: 7178.Google Scholar
van der Wal, D. (1998). The impact of the grain-size distribution of nourishment sand on aeolian sand transport. Journal of Coastal Research 14: 620631.Google Scholar
van der Wal, D. (2000). Grain-size-selective aeolian sand transport on a nourished beach. Journal of Coastal Research 16: 896908.Google Scholar
van der Wal, D. (2004). Beach-dune interaction in nourishment areas along the Dutch coast. Journal of Coastal Research 20: 317325.Google Scholar
van der Windt, H. J., Swart, J. A. A., and Keulartz, J. (2007). Nature and landscape planning: exploring the dynamics of valuation, the case of The Netherlands. Landscape and Urban Planning 79: 218228.Google Scholar
van Duin, M. J. P., Wiersma, N. R., Walstra, D. J. R., van Rijn, L. C., and Stive, M. J. F. (2004). Nourishing the shoreface: observations and hindcasting of the Egmond case, The Netherlands. Coastal Engineering 51: 813837.Google Scholar
van Egmond, E. M., van Bodegom, P. M., Berg, M. P., et al. (2018). A mega-nourishment creates novel habitat for intertidal macroinvertebrates by enhancing habitat relief of the sandy beach. Estuarine, Coastal and Shelf Science 207: 232241.Google Scholar
van Koningsveld, M. and Lescinski, J. (2007). Decadal scale performance of coastal maintenance in The Netherlands. Shore and Beach 75(1): 2036.Google Scholar
van Koningsveld, M. and Mulder, J. P. M. (2004). Sustainable coastal policy developments in The Netherlands. A systematic approach. Journal of Coastal Research 20: 375385.Google Scholar
van Koningsveld, M., Stive, M. J. F., Mulder, J. P. M., de Vriend, H. J., Ruessink, B. G., and Dunsbergen, D. W. (2003). Usefulness and effectiveness of coastal research: a matter of perception. Journal of Coastal Research 19: 441461.Google Scholar
van Leeuwen, S., Dodd, N., Calvete, D., and Falqués, A. (2007). Linear evolution of a shoreface nourishment. Coastal Engineering 54: 417431.Google Scholar
van Puijenbroek, M. E. B., Limpens, J., de Groot, A. V., et al. (2017). Embryo dune development drivers: beach morphology, growing season precipitation, and storms. Earth Surface Processes and Landforms 42: 17331744.Google Scholar
van Tomme, J., Vanden Eede, S., Speybroeck, J., Degraer, S., and Vincx, M. (2013). Macrofaunal sediment selectivity considerations for beach nourishment programmes. Marine Environmental Research 84: 1016.Google Scholar
Vandemark, L. M. (2000). Understanding opposition to dune restoration: attitudes and perceptions of beaches and dunes as natural coastal landforms. Unpublished Ph.D. dissertation. Department of Geography, Rutgers University, New Brunswick, NJ.Google Scholar
Vandenbohede, A., Lebbe, L., Adams, R., Cosyns, E., Durinck, P., and Zwaenepoel, A. (2010). Hydrogeological study for improved nature restoration in dune ecosystems-Kleyne Vlakte case study. Journal of Environmental Management 91: 23852395.Google Scholar
Verstrael, T. J. and van Dijk, A. J. (1996). Trends in breeding birds in Dutch dune areas. In Salman, A. H. P. M., Langeveld, M. J., and Bonazountas, M. (Eds.), Coastal Management and Habitat Conservation. Leiden: EUCC, pp. 403416.Google Scholar
Vestergaard, P. (2013). Natural plant diversity development on a man-made dune system. In Martínez, M. L., Gallego-Fernández, J. B., and Hesp, P. A. (Eds.), Restoration of Coastal Dunes. New York: Springer, pp. 4966.Google Scholar
Vestergaard, P. and Hansen, K. (1992). Changes in morphology and vegetation of a man-made beach-dune system by natural processes. In Carter, R. W. G., Curtis, T. G. F., and Sheehy-Skeffington, M. J. (Eds.), Coastal Dunes: Geomorphology, Ecology and Management for Conservation. Rotterdam: A.A. Balkema, pp. 165176.Google Scholar
Vieira da Silva, G., Hamilton, D., Murray, T., et al. (2020). Impacts of a multi-purpose artificial reef on hydrodynamics, waves and long-term beach morphology. Journal of Coastal Research SI95: 706710.Google Scholar
Viola, S. M., Hubbard, D. M., Dugan, J. E., and Schooler, N. K. (2014). Burrowing inhibition by fine textured beach fill: implications for recovery of beach ecosystems. Estuarine, Coastal and Shelf Science 150: 142148.Google Scholar
Vousdoukas, M. I., Bouziotas, D., Giardino, A., Bouwer, L. M., Voukoucalas, E., and Feyen, L. (2018). Understanding epistemic uncertainty in large-scale coastal flood risk assessment for present and future climates. Natural Hazards and Earth System Sciences 18: 21272142.Google Scholar
Waks, L. J. (1996). Environmental claims and citizen rights. Environmental Ethics 18: 133148.Google Scholar
Walker, I. J., Eamer, J. B. R., and Darke, I. B. (2013). Assessing significant geomorphic changes and effectiveness of dynamic restoration in a coastal dune ecosystem. Geomorphology 199: 192204.Google Scholar
Walmsley, C. A. and Davey, A. J. (1997a). The restoration of coastal shingle vegetation: effects of substrate composition on the establishment of seedlings. Journal of Applied Ecology 34: 143153.Google Scholar
Walmsley, C. A. and Davey, A. J. (1997b). The restoration of coastal shingle vegetation: effects of substrate composition on the establishment of container-grown plants. Journal of Applied Ecology 34: 154165.Google Scholar
Wamsley, T. V., Waters, J. P., and King, D. B. (2011). Performance of experimental low volume beach fill and clay core dune shore protection project. Journal of Coastal Research SI59: 202210.Google Scholar
Wanders, E. (1989). Perspectives in coastal dune management. In van der Meulen, F., Jungerius, P. D., and Visser, J. H. (Eds.), Perspectives in Coastal Dune Management. The Hague: SPB Academic Publishing, pp. 141148.Google Scholar
Warren, R. S., Fell, P. E., Rozsa, R., et al. (2002). Salt marsh restoration in Connecticut: 20 years of science and management. Restoration Ecology 10: 497513.Google Scholar
Warrick, J. A., Stevens, A. W., Miller, I. M., Harrison, S. R., Ritchie, A. C., and Gelfenbaum, G. (2019). World’s largest dam removal reverses coastal erosion. Scientific Reports 9: 13968.Google Scholar
Watson, J. J., Kerley, G. I. H., and McLachlan, A. (1997). Nesting habitat of birds breeding in a coastal dunefield, South Africa and management implications. Journal of Coastal Research 13: 3645.Google Scholar
Webb, C. E., Oliver, I., and Pik, A. J. (2000). Does coastal foredune stabilization with Ammophila arenaria restore plant and arthropod communities in Southeast Australia. Restoration Ecology 8: 283288.Google Scholar
Wells, J. T. and McNinch, J. (1991). Beach scraping in North Carolina with special reference to its effectiveness during Hurricane Hugo. Journal of Coastal Research SI8: 249261.Google Scholar
Westhoff, V. (1985). Nature management in coastal areas of Western Europe. Vegetatio 62: 523532.Google Scholar
Westhoff, V. (1989). Dunes and dune management along the North Sea Coasts. In van der Meulen, F., Jungerius, P. D., and Visser, J. H. (Eds.), Perspectives in Coastal Dune Management. The Hague: SPB Academic Publishing, pp. 4151.Google Scholar
Westman, W. E. (1991). Ecological restoration projects: measuring their performance. The Environmental Professional 13: 207215.Google Scholar
White, P. S. and Walker, J. L. (1997). Approximating nature’s variation: selecting and using reference information in restoration ecology. Restoration Ecology 5: 338349.Google Scholar
Wiedemann, A. M. and Pickart, A. J. (1996). The Ammophila problem on the northwest coast of North America. Landscape and Urban Planning 34: 287299.Google Scholar
Wiedemann, A. M. and Pickart, A. J. (2004). Temperate zone coastal dunes. In Martínez, M. L. and Psuty, N. P. (Eds.), Coastal Dunes, Ecology and Conservation. Berlin: Springer-Verlag, pp. 5365.Google Scholar
Wiegel, R. L. (1993). Artificial beach construction with sand/gravel made by crushing rock. Shore and Beach 61(4): 2829.Google Scholar
Wiens, J. A. and Hobbs, R. J. (2015). Integrating conservation and restoration in a changing world. Bioscience 65: 302312.Google Scholar
Williams, A. T. and Davies, P. (2001). Coastal dunes of Wales; vulnerability and protection. Journal of Coastal Conservation 7: 145154.Google Scholar
Williams, A. and Feagin, R. (2010). Sargassum as a natural solution to enhance dune plant growth. Environmental Management 46: 738747.Google Scholar
Williams, A. T. and Tudor, D. T. (2001). Temporal trends in litter dynamics at a pebble pocket beach. Journal of Coastal Research 17: 137145.Google Scholar
Williams, A. T., Davies, P., Curr, R., et al. (1993). A checklist assessment of dune vulnerability and protection in Devon and Cornwall, UK. In Coastal Zone 1993. New York: American Society of Civil Engineers, pp. 33943408.Google Scholar
Williams, A. T., Giardino, A., and Pranzini, E. (2016). Canons of coastal engineering in the United Kingdom: seawalls/groins, a century of change? Journal of Coastal Research 32: 11961211.Google Scholar
Williams, G. D. and Thom, R. M. (2001). Marine and Estuarine Shoreline Modification Issues. White paper. Olympia, WA: Washington Department of Fish and Wildlife, Department of Ecology.Google Scholar
Willis, C. M. and Griggs, G. B. (2003). Reductions in fluvial sediment discharge by coastal dams in California and implications for beach sustainability. The Journal of Geology 111: 167182.Google Scholar
Wong, P. P. (Ed.). (1993). Tourism vs Environment: The Case for Coastal Areas. Dordrecht: Kluwer Academic Publishers.Google Scholar
Wood, D. W. and Bjorndal, K. A. (2000). Relation of temperature, moisture, salinity, and slope to nest site selection in loggerhead sea turtles. Copeia 1: 119128.Google Scholar
Woodhouse, W. W. (1974). Stabilizing Coastal Dunes. Reprint No. 70. Raleigh: North Carolina University Sea Grant.Google Scholar
Woodhouse, W. W. and Hanes, R. E. (1967). Dune Stabilization with Vegetation on the Outer Banks of North Carolina. TM-22. Washington, DC: U.S. Army Coastal Engineering Research Center.Google Scholar
Woodhouse, W. W. Jr., Seneca, E. D., and Broome, S. W. (1977). Effect of species on dune grass growth. International Journal of Biometeorology 21: 256266.Google Scholar
Woodruff, P. E. and Schmidt, D. V. (1999). Florida beach preservation – a review. Shore and Beach 67(4): 713.Google Scholar
Wooldridge, T., Henter, H. J., and Kohn, J. R. (2016). Effects of beach replenishment on intertidal invertebrates: a 15-month, eight beach study. Estuarine, Coastal and Shelf Science 175: 2433.Google Scholar
Wootton, L. S., Halsey, S. D., Bevaart, K., McGough, A., Ondreicka, J., and Patel, P. (2005). When invasive species have benefits as well as costs: managing Carex Kobomugi (Asiatic sand sedge) in New Jersey’s coastal dunes. Biological Invasions 7: 10171027.Google Scholar
Wootton, L., Miller, J., Miller, C., Peek, M., Williams, A., and Rowe, P. (2016). Dune Manual. Sandy Hook: New Jersey Sea Grant Consortium.Google Scholar
Wortley, L., Hero, J.-M., and Howes, M. (2013). Evaluating ecological restoration success: a review of the literature. Restoration Ecology 21: 537543.Google Scholar
Wright, L. D. and Short, A. D. (1984). Morphodynamic variability of surf zones and beaches: a synthesis. Marine Geology 56: 93118.Google Scholar
Wright, S. and Butler, K. S. (1984). Land use and economic impacts of a beach nourishment project. In Coastal Zone 83, post conference volume. Sacramento: California State Lands Commission, pp. 118.Google Scholar
Zarkogiannis, S. D., Kontakiotis, G., Vousdoudas, M. I., Velegrakis, A. F., and Collins, M. B. (2018). Scarping of artificially-nourished mixed sand and gravel beaches: sedimentological characteristics of Hayling Island beach, Southern England. Coastal Engineering 133: 112.Google Scholar
Zedler, J. B. (1991). The challenge of protecting endangered species habitat along the southern California coast. Coastal Management 19: 3553.Google Scholar
Zelo, I., Shipman, H., and Brennan, J. (2000). Alternative Bank Protection Methods for Puget Sound Shorelines. Ecology Publication #00-06-012. Olympia, WA: Washington Department of Ecology.Google Scholar
Zielinski, S., Botero, C. M., and Yanes, A. (2019). To clean or not to clean? A critical review of beach cleaning methods and impacts. Marine Pollution Bulletin 139: 390401.Google Scholar
Zinnert, J. C., Via, S. M., Nettleton, B. P., Tuley, P. A., Moore, L. J., and Stallins, J. A. (2020). Connectivity in coastal systems: Barrier island vegetation influences upland migration in a changing climate. Global Change Biology 25: 24192430.Google Scholar
Zmyslony, J. and Gagnon, D. (2000). Path analysis of spatial predictors of front-yard landscapes: a random process? Landscape and Urban Planning 40: 295307.Google Scholar

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  • References
  • Karl F. Nordstrom, Rutgers University, New Jersey
  • Adaptation by Nancy L. Jackson, New Jersey Institute of Technology
  • Book: Beach and Dune Restoration
  • Online publication: 09 December 2021
  • Chapter DOI: https://doi.org/10.1017/9781108866453.011
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  • References
  • Karl F. Nordstrom, Rutgers University, New Jersey
  • Adaptation by Nancy L. Jackson, New Jersey Institute of Technology
  • Book: Beach and Dune Restoration
  • Online publication: 09 December 2021
  • Chapter DOI: https://doi.org/10.1017/9781108866453.011
Available formats
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  • References
  • Karl F. Nordstrom, Rutgers University, New Jersey
  • Adaptation by Nancy L. Jackson, New Jersey Institute of Technology
  • Book: Beach and Dune Restoration
  • Online publication: 09 December 2021
  • Chapter DOI: https://doi.org/10.1017/9781108866453.011
Available formats
×