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Restoration of Seagrasses: With Economic Analysis

Published online by Cambridge University Press:  24 August 2009

Anitra Thorhaug  and
C. Bruce Austin
Anitra Thorhaug
Affiliation:
Department of Microbiology, School of Medicine, University of Miami, 10 Rickenbacker Causeway, Miami, Florida 33149, U.S.A.
C. Bruce Austin
Affiliation:
School of Economics, University of Miami, Coral Gables, Florida 33134, and Department of Biology & Living Resources, RSMAS, 10 Rickenbacker Causeway, Miami, Florida 33149, U.S.A.
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Extract

The technique of restoration of populations of land plants is an old one that is well understood by scientists, agronomists, forestry experts, and the general public. However, only recently has attention been turned to restoring underwater areas with socalled seagrasses. From 1947 onwards, attempts have been made to restore suitable marine areas by using important species; however, only very recently (from August 1973) have large-scale restoration projects been undertaken.

The efforts that have been made to replant various seagrass species by different techniques are reviewed, but only two seagrasses, Zostera noltii and Thalassia testudinum, have been restored on a large scale. Both of these can be restored successfully; however, the seeding method of Thalassia appears to be the most practical operation of all, and the most potentially valuable for future research into large-scale restoration, as it allows flexibility of location and of depth of transplantation, and involves the minimum of damage to the donor site. It also ensures the most rapid regrowth, besides being in the long run the most economical method yet devised of restoring a seagrass community. An economic model (see Technical Appendix to this paper) and analysis for restoration costs are given and finally a wide range of uses of restoration of such beds of seagrasses are enumerated.

Type
Main Papers
Information
Environmental Conservation , Volume 3 , Issue 4 , Winter 1976 , pp. 259 - 266
Copyright
Copyright © Foundation for Environmental Conservation 1976

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References

Addy, C. E. (1947 a). Eelgrass planting guide. Maryland Conserv., 24, pp. 16–7.Google Scholar
Addy, C. E. (1947b). Germination of eelgrass seed. J. Wildlife Management, 11, pp. 279–80.CrossRefGoogle Scholar
Bader, R. G., Roessler, M. A. & Thorhaug, A. (1972). Thermal pollution of a tropical marine estuary. Pp. 245–51 in Marine Pollution and Sea Life. Fishing News (Books) Ltd, Surrey, England: xi + 451 pp., illustr.Google Scholar
Breedveld, Van J. (1976). Transplanting of seagrasses with emphasis on the importance of substrate. Fla Mar. Res. Publ, St Petersburg, Florida, No. 126, 26 pp., illustr.Google Scholar
Eleuterius, L. N. (1975). Submergent vegetation for bottom stabilization. Pp. 439–56 in Estuarine Research, Vol. II. Academic Press, New York, N.Y.: 545 pp., illustr.Google Scholar
Fuss, C. M. Jr, & Kelly, J. A. Jr, (1969). Survival and growth of seagrasses transplanted under artificial conditions. Bull. Mar. Sci., 19, pp. 351–65, illustr.Google Scholar
Hartog, C. den (1972). The seagrasses of the world. Verh. Konin. Nederl. Acad. Wetens. Natuurk., 59(1), pp. 1275.Google Scholar
Kelly, J. A. Jr, Fuss, C. M. Jr, & Hall, J. R. (1971). The transplanting and survival of Turtle-grass, Thalassia testudinum, Boca Ciega Bay, Florida. Fish. Bull., 6(2), pp. 273–80, illustr.Google Scholar
Larkum, A. W. D. (1976). Ecology of Botany Bay, I. Growth of Posidonia australis (Brown) Hook, found in Botany Bay and other bays of the Sydney Basin. Austral. J. Fresh, and Marine Res., 27(1), pp. 217–22.CrossRefGoogle Scholar
Mcroy, C. P. & Helffrich, C. (in press). Seagrass Ecosystems: A Scientific Perspective. Marcel Dekker, New York.Google Scholar
Phillips, R. C. (1960). Observations on the ecology and distribution of the Florida seagrasses. Fla State Bd Conserv., Mar. Lab. Prof. Pap. Ser., 2, 72 pp., illustr.Google Scholar
Phillips, R. C. (1972). Ecological Life History of Zostera marina L. (Eelgrass) in Puget Sound, Washington. Unpublished Ph.D. thesis, University of Washington, Seattle, Washington: 154 pp., illustr.Google Scholar
Phillips, R. C. (1974). Transplantation of seagrasses with special emphasis on Zostera marina, L. Aquaculture, 4, pp. 161–76, illustr.CrossRefGoogle Scholar
Ranwell, D. S., Wyer, D. W., Boorman, L. A., Pizzey, J. M. & Waters, R. J. (1974). Zostera transplants in Norfolk and Suffolk, Great Britain. Aquaculture, 4, pp. 185–98, illustr.Google Scholar
Rasmussen, E. (1973). Systematics and ecology of the Isfjord marine fauna (Denmark). Ophelia, 11, pp. 1495, illustr.CrossRefGoogle Scholar
Roessler, M. A., Beardsley, G. L. & Smith, R. (1974). Benthic communities of Biscayne Bay, Florida. University of Miami Sea Grant Coastal Zone Managemt Bull., No. 13, 19 pp., illustr.Google Scholar
Sylva, D. P. De (1976). Fishes of Biscayne Bay, Florida. Pp. 181–90 in Biscayne Bay: Past/Present/Future (Ed. Thorhaug, A.). University of Miami, Miami, Florida: iv + 315 pp., illustr.Google Scholar
Thayer, G., Wolfe, D. & Williams, R. W. (1975). Man's impact on seagrass ecosystems. Amer. Sci., 63(3), pp. 288–96, illustr.Google Scholar
Thorhaug, A. (1974). Transplantation of the seagrass Thalassia testudinum Konig. Aquaculture, 4, pp. 177–83, illustr.Google Scholar
Thorhaug, A. & Hixon, R. (1975). Revegetation of Thalassia testudinum in a multiply stressed estuary, North Biscayne Bay, Florida. Pp. 12–7 in Second Annual Congress on Restoration of Coastal Vegetation in Florida (Ed. Lewis, R. R.). Hillsborough College Press, Tampa, Florida: 214 pp., illustr.Google Scholar
Thorhaug, A. & Roessler, M. A. (in press). Seagrass community dynamics in a subtropical estuarine lagoon. Aquatic Botany.Google Scholar
Thorhaug, A., Segar, D. & Roessler, M. A. (1973). Impact of a power-plant on a subtropical estuarine environment. Mar. Poll. Bull., 7(11), pp. 166–9, illustr.CrossRefGoogle Scholar
Voss, G. L. (1976). Invertebrates of Biscayne Bay. Pp. 173–9 in Biscayne Bay: Past/Present/Future (Ed. Thorhaug, A.). University of Miami, Miami, Florida: iv + 315 pp., illustr.Google Scholar
Wanless, H. (1976). Geologic setting and recent sediments of the Biscayne Bay Region, Florida. Pp. 131 in Biscayne Bay: Past I Present I Future (Ed. Thorhaug, A.). University of Miami, Miami, Florida: iv + 315 pp., illustr.Google Scholar
Zieman, J. C. (1975). Dynamic and quantitative aspects of the ecology of Turtle-grass, Thalassia testudinum. Pp. 541–62 in International Estuarine Restoration Conference (Ed. Costlow, J. D., Williams, A., & Cronin, E.). Academic Press, New York: xi + 738 pp., illustr.Google Scholar