The effects of oil palm plantations on the functional diversity of Amazonian birds

Sara M. Almeida; Larissa C. Silva; Maíra R. Cardoso; Pablo V. Cerqueira; Leandro Juen; Marcos P. D. Santos

doi:10.1017/S0266467416000377

The effects of oil palm plantations on the functional diversity of Amazonian birds

Published online by Cambridge University Press: 05 August 2016

Leandro Juen and

Sara M. Almeida*: Affiliation:
Graduate Program in Zoology, Universidade Federal do Pará/Museu Paraense Emílio Goeldi, Caixa Postal 479, CEP 66075-110, Belém, Pará, Brazil
Larissa C. Silva: Affiliation:
Graduate Program in Zoology, Universidade Federal do Pará/Museu Paraense Emílio Goeldi, Caixa Postal 479, CEP 66075-110, Belém, Pará, Brazil
Maíra R. Cardoso: Affiliation:
Graduate Program in Zoology, Universidade Federal do Pará/Museu Paraense Emílio Goeldi, Caixa Postal 479, CEP 66075-110, Belém, Pará, Brazil
Pablo V. Cerqueira: Affiliation:
Graduate Program in Zoology, Universidade Federal do Pará/Museu Paraense Emílio Goeldi, Caixa Postal 479, CEP 66075-110, Belém, Pará, Brazil
Leandro Juen: Affiliation:
Graduate Program in Zoology, Universidade Federal do Pará/Museu Paraense Emílio Goeldi, Caixa Postal 479, CEP 66075-110, Belém, Pará, Brazil Institute of Biological Sciences, Universidade Federal do Pará (UFPA), Belém, Pará, Brazil
Marcos P. D. Santos: Affiliation:
Graduate Program in Zoology, Universidade Federal do Pará/Museu Paraense Emílio Goeldi, Caixa Postal 479, CEP 66075-110, Belém, Pará, Brazil Institute of Biological Sciences, Universidade Federal do Pará (UFPA), Belém, Pará, Brazil
*: 1 Corresponding author. Email: [email protected]

Article contents

Abstract:
References

Get access

Rights & Permissions

Abstract:

Oil palm plantations are rapidly expanding in tropical areas, although the nature of the impacts on the functional roles of the different species in the ecosystem is poorly understood. The present study is the first assessment of how oil palm affects the functional diversity of birds in the Brazilian Amazon and tests the hypothesis that converting forest to oil palm decreases functional diversity of bird communities, selecting species more tolerant to environmental disturbances. We conducted point counts to survey bird communities in 16 plots in the eastern Amazon. We sampled 32 points in riparian forest, 128 in oil palm and 160 in forested habitats. To test whether the conversion of forest into oil palm plantations affects functional diversity of birds we calculated the FD (Functional Diversity) and FRic (Functional Richness) indices. To examine whether oil palm plantations select species functionally more similar than expected by chance we used a null model (SES.FD). FD was significantly higher in the forest plots in comparison with riparian forests and oil palm, and lower in oil palm when compared with riparian forests. FRic, in turn, was greater in forest plots than in oil palm and in riparian forest. These results show that the conversion of forested areas to oil palm represents a great loss of functional strategies. The SES values indicate that in forested habitats bird communities tend to be functionally clustered while in the oil palm they are functionally overdispersed. The functional traits most affected by oil palm were those associated with diet and foraging stratum. In short, oil palm plantations reduced functional diversity of birds, although the presence of riparian forests within the plantations and the fragments of forest adjacent are extremely important for the maintenance of ecosystem services.

Keywords

classification tree ecological corridors Elaeis guineensis functional overdispersion traits

Type: Research Article
Information: Journal of Tropical Ecology , Volume 32 , Issue 6 , November 2016 , pp. 510 - 525

DOI: https://doi.org/10.1017/S0266467416000377 [Opens in a new window]
Copyright: Copyright © Cambridge University Press 2016

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

LITERATURE CITED

ARATRAKORN, S., THUNHIKORN, S. & DONALD, P. F. 2006. Changes in bird communities following conversion of lowland forest to oil palm and rubber plantations in southern Thailand. Bird Conservation International 16:71–82.Google Scholar

AZHAR, B., LINDENMAYER, D. B., WOOD, J., FISCHER, J., MANNING, A., MCELHINNY, C. & ZAKARIA, M. 2013. The influence of agricultural system, stand structural complexity and landscape context on foraging birds in oil palm landscapes. Ibis 155: 297–312.Google Scholar

BASTOS, T. X., MULLER, A. A., PACHECO, N. A., SAMPAIO, S. M. N., ASSAD, E. D. & MARQUES, A. F. S. 2001. Zoneamento de riscos climáticos para a cultura do dendezeiro no estado do Pará. Revista Brasileira de Agrometeorologia 9:564–570.Google Scholar

BAWA, K. S. 1990. Plant–pollinator interactions in a tropical rain forest. Annual Review of Ecology and Systematics 21:339–422.CrossRef Google Scholar

BLITZER, E. J., DORMANN, C. F., HOLZSCHUH, A., KLEIN, A. M., RAND, T. A. & TSCHARNTKE, T. 2012. Spillover of functionally important organisms between managed and natural habitats. Agriculture Ecosystems and Environment 146:34–43.CrossRef Google Scholar

BLONDEL, J., FERRY, C. & FROCHOT, B. 1970. La méthode des indices ponctuels d'abundance (IPA) ou des relevés d'avifaune par “stations d’écoute”. Alauda 38:55–71.Google Scholar

BOLFE, E. L & BATISTELLA, M. 2011. Análise florística e estrutural de sistemas silviagrícolas em Tomé-Açú, Pará. Pesquisa Agropecuária Brasileira 46:1139–1147.CrossRef Google Scholar

BREIMAN, L., FRIEDMAN, J. H., OLSHEN, R. A. & STONE, C. J. 1984. Classification and regression trees. Wadsworth & Brooks/Cole Advanced Books & Software, Monterey. 358 pp.Google Scholar

CORNWELL, W. K., SCHWILK, D. W. & ACKERLY, D. D. 2006. A trait-based test for habitat filtering: convex hull volume. Ecology 87:1465–1471.Google Scholar

CORREA, F. S., JUEN, L., RODRIGUES, L. C., SILVA-FILHO, H. F. & SANTOS-COSTA, M. C. 2015. Effects of oil palm plantations on anuran diversity in the eastern Amazon. Animal Biology 65:321–335.Google Scholar

CUNHA, E. J., MONTAG, L. F. & JUEN, L. 2015. Oil palm crops effects on environmental integrity of Amazonian streams and heteropteran (Hemiptera) species diversity. Ecological Indicators 52:422–429.Google Scholar

DEVELEY, P. F. & PONGILUPPI, T. 2010. Impactos potenciais na avifauna decorrentes das alterações propostas para o Código Florestal Brasileiro. Biota Neotropica 10:43–45.CrossRef Google Scholar

DEVICTOR, V., MOUILLOT, D., MEYNARD, C., JIGUET, F., THUILLER, W. & MOUQUET, N. 2010. Spatial mismatch and congruence between taxonomic, phylogenetic and functional diversity: the need for integrative conservation strategies in a changing world. Ecology Letters 13:1030–1040.CrossRef Google Scholar

DÍAZ, S. & CABIDO, M. 2001. Vive la difference: plant functional diversity matters to ecosystem processes. Trends in Ecology and Evolution 16:646–655.CrossRef Google Scholar

DRAY, S. & DUFOUR, A. B. 2007. The ade4 package: implementing the duality diagram for ecologists. Journal of Statistical Software 22:1–20.Google Scholar

EDWARDS, D. P., HODGSON, J. A., HAMER, K. C., MITCHELL, S. L., AHMAD, A. H., CORNELL, S. J. & WILCOVE, D. S. 2010. Wildlife-friendly oil palm plantations fail to protect biodiversity effectively. Conservation Letters 3:236–242.CrossRef Google Scholar

EDWARDS, F. A., EDWARDS, D. P., HAMER, K. C. & DAVIES, R. G. 2013. Impacts of logging and conversion of rainforest to oil palm on the functional diversity of birds in Sundaland. Ibis 155:313–326.CrossRef Google Scholar

EDWARDS, F. A., EDWARDS, D. P., LARSEN, T. H., HSU, W. W., BENEDICK, S., CHUNG, A., VUN KHEN, C., WILCOVE, D. S. & HAMER, K. C. 2014. Does logging and forest conversion to oil palm agriculture alter functional diversity in a biodiversity hotspot? Animal Conservation 17:163–173.CrossRef Google Scholar

ELMQVIST, T., FOLKE, C., NYSTROM, M., PETERSON, G., BENGSTON, J., WALKER, B. & NORBERG, J. 2003. Response diversity and ecosystem resilience. Frontiers in Ecology and the Environment 1:488–494.CrossRef Google Scholar

FAGAN, W. 1997. Omnivory as a stabilizing feature of natural communities. American Naturalist 150:554–567.CrossRef Google Scholar PubMed

FITZHERBERT, E. B., STRUEBIG, M. J., MOREL, A., DANIELSEN, F., BRÜHL, C. A., DONALD, P. F. & PHALAN, B. 2008. How will oil palm expansion affect biodiversity? Trends in Ecology and Evolution 23:538–545.CrossRef Google Scholar PubMed

FLYNN, D. F. B., GOGOL-PROKURAT, M., NOGEIRE, T., MOLINARI, N., RICHERS, B. T., LIN, B. B., SIMPSON, N., MAYFIELD, M. M. & DECLERCK, F. 2009. Loss of functional diversity under land use intensification across multiple taxa. Ecology Letters 12:22–33.CrossRef Google Scholar PubMed

GALETTI, M. & ALEIXO, A. 1998. Effects of palm heart harvesting on avian frugivores in the Atlantic rain forest of Brazil. Journal of Applied Ecology 35:286–293.CrossRef Google Scholar

HAWES, J., BARLOW, J., GARDNER, T. A. & PERES, C. A. 2008. The value of forest strips for understorey birds in an Amazonian plantation landscape. Biological Conservation 141:2262–2278.CrossRef Google Scholar

HIDASI-NETO, J., BARLOW, J. & CIANCIARUSO, M. V. 2012. Bird functional diversity and wildfires in the Amazon: the role of forest structure. Animal Conservation 15:407–415.Google Scholar

HUTCHINSON, G. E. 1957. Concluding remarks. Cold Spring Harbor Symposia on Quantitative Biology 22:415–427.CrossRef Google Scholar

KEMBEL, S. W., COWAN, P. D., HELMUS, M. R., CORNWELL, W. K., MORLON, H., ACKERLY, D. D., BLOMBERG, S. P. & WEBB, C. O. 2010. Picante: R tools for integrating phylogenies and ecology. Bioinformatics 26:1463–1464.Google Scholar

KOH, L. P. 2008. Can oil palm plantations be made more hospitable for forest butterflies and birds? Journal of Applied Ecology 45:1002–1009.CrossRef Google Scholar

KOH, L. P., LEVANG, P. & GHAZOUL, J. 2009. Designer landscapes for sustainable biofuels. Trends in Ecology and Evolution 24:431–438.CrossRef Google Scholar PubMed

LALIBERTÉ, E. & LEGENDRE, P. 2010. A distance-based framework for measuring functional diversity from multiple traits. Ecology 91:299–305.Google Scholar

LEES, A. C. & PERES, C. A. 2008. Conservation value of remnant riparian forest corridors of varying quality for Amazonian birds and mammals. Conservation Biology 22:439–449.Google Scholar

LEES, A. C., MOURA, N. G., ALMEIDA, A. S. & VIEIRA, I. C. G. 2015. Poor prospects for avian biodiversity in Amazonian oil palm. PLoS ONE 10:e0122432.Google Scholar

LOVEJOY, T. E. 1974. Bird diversity and abundance in Amazon forest communities. Living Bird 13:127–191.Google Scholar

LUCK, G. W., CARTER, A. & SMALLBONE, L. 2013. Changes in bird functional diversity across multiple land uses: interpretations of functional redundancy depend on functional group identity. PLoS ONE 8:e63671–e63671.Google Scholar

MALHI, Y., GARDNER, T. A., GOLDSMITH, G. R., SILMAN, M. R. & ZELAZOWSKI, P. 2014. Tropical forests in the Anthropocene. Annual Review of Environment and Resources 39: 125–159.Google Scholar

MOUCHET, M. A., VILLÉGER, S., MASON, N. W. H. & MOUILLOT, D. 2010. Functional diversity measures: an overview of their redundancy and their ability to discriminate community assembly rules. Functional Ecology 24:867–876.CrossRef Google Scholar

NAMBA, T., TANABE, K. & MAEDA, N. 2008. Omnivory and stability of food webs. Ecological Complexity 5:73–85.CrossRef Google Scholar

PAVOINE, S., VALLET, J., DUFOUR, A-B., GACHET, S. & DANIEL, H. 2009. On the challenge of treating various types of variables: application for improving the measurement of functional diversity. Oikos 118:391–402.CrossRef Google Scholar

PERFECTO, I., VANDREMEER, J. H., BAUTISTA, G. L., NUÑEZ, G. I., GREENBERG, R., BICHIER, P. & LANGRIDGE, S. 2004. Greater predation in shaded coffee farms: the role of resident neotropical birds. Ecology 85:2677–2681.CrossRef Google Scholar

PETCHEY, O. L. & GASTON, K. 2006. Functional diversity: back to basics and looking forward. Ecology Letters 9:741–758.CrossRef Google Scholar PubMed

PETCHEY, O. L., EVANS, K. L., FISHBURN, I. S. & GASTON, K. J. 2007. Low functional diversity and no redundancy in British avian assemblages. Journal of Animal Ecology 76: 977–985.Google Scholar

PIACENTINI, V. Q., ALEIXO, A., AGNE, C. E., MAURÍCIO, G. N., PACHECO, J. F., BRAVO, G. A., BRITO, G. R. R., NAKA, L. N., OLMOS, F., POSSO, S., SILVEIRA, L. F., BETINI, G. S., CARRANO, E., FRANZ, I., LEES, A. C., LIMA, L. M., PIOLI, D., SCHUNCK, F., AMARAL, F. R., BENCKE, G. A., COHN-HAFT, M., FIGUEIREDO, L. F. A., STRAUBE, F. C. & CESARI, E. 2015. Annotated checklist of the birds of Brazil by the Brazilian Ornithological Records Committee. Revista Brasileira de Ornitologia 23:91–298.CrossRef Google Scholar

PIZO, M. A. & GALETTI, M. 2010. Métodos e perspectivas do estudo da frugivoria e dispersão de sementes por aves. pp. 493–503 in Von Matter, S., Straube, F. C., Accordi, I. A., Piacentini, V. & Cândido, J. F. Jr (eds.). Ornitologia e conservação: ciência aplicada, técnicas de pesquisa e levantamento. Ed. Technical Books, Rio de Janeiro.Google Scholar

PORTES, C. E. B., CARNEIRO, L. S., SCHUNCK, F., SILVA, M. S., ZIMMER, K. J., WHITTAKER, A., POLETTO, F., SILVEIRA, L. F. & ALEIXO, A. 2011. Annotated checklist of birds recorded between 1998 and 2009 at nine areas in the Belém area of endemism, with notes on some range extensions and the conservation status of endangered species. Revista Brasileira Ornitologia 19:167– 184.Google Scholar

PRESCOTT, G. W., GILROY, J. J., HAUGAASEN, T., URIBE, C. A. M., FOSTER, W. A. & EDWARDS, D. P. 2016. Reducing the impacts of Neotropical oil palm development on functional diversity. Biological Conservation 197:139–145.CrossRef Google Scholar

ROSENBERG, G. H. 1990. Habitat specialization and foraging behavior by birds of Amazonian river islands in northeastern Peru. Condor 92:427–443.CrossRef Google Scholar

SAVILAAKSO, S., GARCIA, C., GARCIA-ULLOA, J., GHAZOUL, J., GROOM, M., GUARIGUATA, M. R., LAUMONIER, Y., NASI, R., PETROKOFSKY, G., SNADDON, J. & ZRUST, M. 2014. Systematic review of effects on biodiversity from oil palm production. Environmental Evidence 3:4.Google Scholar

SCHROEDER, M. S., CULHANE, A. C., QUACKENBUSH, J. & HAIBE-KAINS, B. 2011. survcomp: an R/Bioconductor package for performance assessment and comparison of survival models. Bioinformatics 27:3206–3208.Google Scholar

ŞEKERCIOĞLU, Ç. H. 2006. Increasing awareness of avian ecological function. Trends in Ecology and Evolution 21:464–471.CrossRef Google Scholar PubMed

ŞEKERCIOĞLU, Ç. H. 2012. Bird functional diversity and ecosystem services in tropical forests, agroforests and agricultural areas. Journal of Ornithology 153:S153–S161.CrossRef Google Scholar

ŞEKERCIOĞLU, Ç. H., DAILY, G. C. & EHRLICH, P. R. 2004. Ecosystem consequences of bird declines. Proceedings of the National Academy of Sciences USA 101:18042–18047.Google Scholar

SOBRAL, F. L. & CIANCIARUSO, M. V. 2015. Functional and phylogenetic structure of forest and savanna bird assemblages across spatial scales. Ecography 38:1–9.Google Scholar

TEWS, J., BROSE, U., GRIMM, V., TIELBÖRRGER, K., WICHMANN, M. C., SCHWAGER, M. & JELTSCH, F. 2004. Animal species diversity driven by habitat heterogeneity/diversity: the importance of keystone structures. Journal of Biogeography 31:79–92.Google Scholar

TILMAN, D. 2001. Functional diversity. pp. 109–120 in Levin, S. A. (ed.). Encyclopedia of biodiversity. Academic Press, San Diego.CrossRef Google Scholar

TILMAN, D., FARGIONE, J., WOLFF, B., ANTONIO, C. D., DOBSON, A., HOWARTH, R., SCHINDLER, D., SCHLESINGER, W. H., SIMBERLOFF, D. & SWACKHAMER, D. 2001. Forecasting agriculturally driven global environmental change. Science 292:281–284.Google Scholar

VIEIRA, I. C. G., TOLEDO, P. M., SILVA, J. M. C. & HIGUCHI, H. 2008. Deforestation and threats to the biodiversity of Amazonia. Brazilian Journal of Biology 68:949–956.CrossRef Google Scholar

VIELLIARD, J. M. E., ALMEIDA, M.E.C., ANJOS, L. & SILVA, W. R. 2010. Levantamento quantitativo por pontos de escuta e o Índico Pontual de Abundância (IPA). Pp. 47–60 in Von Matter, S., Straube, F. C., Accordi, I. A, Piacentini, V. & Cândido, J. F. Jr (eds.). Ornitologia e conservação: ciência aplicada, técnicas de pesquisa e levantamento. Ed. Technical Books, Rio de Janeiro.Google Scholar

VILLÉGER, S., MASON, N. W. H. & MOUILLOT, D. 2008. New multidimensional functional diversity indices for a multifaceted framework in functional ecology. Ecology 89:2290–2301.Google Scholar

VILLELA, A. A., JACCOUD, D., ROSA, L. P. & FREITAS, M. V. 2014. Status and prospects of oil palm in the Brazilian Amazon. Biomass Bioenergy 67:270–278.Google Scholar

WHITLOCK, M. C. 2005. Combining probability from independent tests: the weighted Z-method is superior to Fisher's approach. Journal of Evolutionary Biology 18:1368–1373.Google Scholar

WIENS, J. A. & JOHNSTON, R. F. 1977. Adaptative correlates of granivory in birds. pp. 301–340 in Pinowski, J. & Kendeigh, S. C. (eds.). Granivorous birds in ecosystems. Cambridge University Press, Cambridge.Google Scholar

WILMAN, H., BELMAKER, J., SIMPSON, J., DE LA ROSA, C., RIVADENEIRA, M. M. & JETZ, W. 2014. EltonTraits 1.0: Species-level foraging attributes of the world's birds and mammals. Ecology 95:2027.Google Scholar

ZANETTE, L., DOYLE, P. & TRÉMONT, S. 2000. Food shortage in small fragments: evidence from an area-sensitive passerine. Ecology 81:1654–1666.Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Cunha, Erlane José and Juen, Leandro 2017. Impacts of oil palm plantations on changes in environmental heterogeneity and Heteroptera (Gerromorpha and Nepomorpha) diversity. Journal of Insect Conservation, Vol. 21, Issue. 1, p. 111.

Knowlton, Jessie L. Phifer, Colin C. Cerqueira, Pablo V. Barro, Fernanda de Carvalho Oliveira, Samuel L. Fiser, Cynthia M. Becker, Nia M. Cardoso, Maíra R. Flaspohler, David J. and Dantas Santos, Marcos Pérsio 2017. Oil Palm Plantations Affect Movement Behavior of a Key Member of Mixed-Species Flocks of Forest Birds in Amazonia, Brazil. Tropical Conservation Science, Vol. 10, Issue. ,

Luiza-Andrade, Ana Brasil, Leandro Schlemmer Benone, Naraiana Loureiro Shimano, Yulie Farias, Ana Paula Justino Montag, Luciano Fogaça Dolédec, Sylvain and Juen, Leandro 2017. Influence of oil palm monoculture on the taxonomic and functional composition of aquatic insect communities in eastern Brazilian Amazonia. Ecological Indicators, Vol. 82, Issue. , p. 478.

Riemann, Jana C. Ndriantsoa, Serge H. Rödel, Mark-Oliver and Glos, Julian 2017. Functional diversity in a fragmented landscape — Habitat alterations affect functional trait composition of frog assemblages in Madagascar. Global Ecology and Conservation, Vol. 10, Issue. , p. 173.

Brito, Thaline F. Contrera, Felipe A. L. Phifer, Colin C. Knowlton, Jessie L. Brasil, Leandro S. Maués, Márcia M. and Silva, Daniel P. 2018. Effects of habitat type change on taxonomic and functional composition of orchid bees (Apidae: Euglossini) in the Brazilian Amazon. Journal of Insect Conservation, Vol. 22, Issue. 3-4, p. 451.

Chellaiah, Darshanaa and Yule, Catherine M. 2018. Riparian buffers mitigate impacts of oil palm plantations on aquatic macroinvertebrate community structure in tropical streams of Borneo. Ecological Indicators, Vol. 95, Issue. , p. 53.

Chellaiah, Darshanaa and Yule, Catherine M. 2018. Litter decomposition is driven by microbes and is more influenced by litter quality than environmental conditions in oil palm streams with different riparian types. Aquatic Sciences, Vol. 80, Issue. 4,

Almeida, Sara Miranda Juen, Leandro Sobral, Fernando Landa and Santos, Marcos Pérsio Dantas 2018. The influence of biogeographic history on the functional and phylogenetic diversity of passerine birds in savannas and forests of the Brazilian Amazon. Ecology and Evolution, Vol. 8, Issue. 7, p. 3617.

OLIVEIRA, Jocieli de ALMEIDA, Sara M. FLORÊNCIO, Fernando P. PINHO, João B. OLIVEIRA, Dalci M. M. LIGEIRO, Raphael and RODRIGUES, Domingos J. 2019. Environmental structure affects taxonomic diversity but not functional structure of understory birds in the southwestern Brazilian Amazon. Acta Amazonica, Vol. 49, Issue. 3, p. 232.

Atiqah, Nurul Yahya, Muhammad Syafiq Aisyah, Siti Ashton-Butt, Adham and Azhar, Badrul 2019. Birds associated with different tree species and structures in oil palm agroforestry landscapes in Malaysia. Emu - Austral Ornithology, Vol. 119, Issue. 4, p. 397.

Cunha, Erlane José Guterres, Alana Patricia Meguy Godoy, Bruno Spacek and Juen, Leandro 2020. Wing dimorphism in semiaquatic bugs (Hemiptera, Heteroptera, Gerromorpha) as a tool for monitoring streams altered by oil palm plantation in the Amazon. Ecological Indicators, Vol. 117, Issue. , p. 106707.

Harada, L. M. Araújo, I. S. Overal, W. L. and Silva, F. A. B. 2020. Comparison of dung beetle communities (Coleoptera: Scarabaeidae: Scarabaeinae) in oil palm plantations and native forest in the eastern Amazon, Brazil. Revista Brasileira de Entomologia, Vol. 64, Issue. 1,

Oliveira, Helon Simões Gouveia, Sidney F. Ruiz-Esparza, Juan and Ferrari, Stephen F. 2020. Fragment size and the disassembling of local bird communities in the Atlantic Forest: A taxonomic and functional approach. Perspectives in Ecology and Conservation, Vol. 18, Issue. 4, p. 304.

Meijaard, Erik Brooks, Thomas M. Carlson, Kimberly M. Slade, Eleanor M. Garcia-Ulloa, John Gaveau, David L. A. Lee, Janice Ser Huay Santika, Truly Juffe-Bignoli, Diego Struebig, Matthew J. Wich, Serge A. Ancrenaz, Marc Koh, Lian Pin Zamira, Nadine Abrams, Jesse F. Prins, Herbert H. T. Sendashonga, Cyriaque N. Murdiyarso, Daniel Furumo, Paul R. Macfarlane, Nicholas Hoffmann, Rachel Persio, Marcos Descals, Adrià Szantoi, Zoltan and Sheil, Douglas 2020. The environmental impacts of palm oil in context. Nature Plants, Vol. 6, Issue. 12, p. 1418.

Knowlton, Jessie Halvorsen, Kathleen Flaspohler, David Webster, Christopher Abrams, Jesse Almeida, Sara Arriaga-Weiss, Stefan Barnett, Brad Cardoso, Maíra Cerqueira, Pablo Córdoba, Diana Dantas-Santos, Marcos Dunn, Jennifer Eastmond, Amarella Jarvi, Gina Licata, Julian Mata-Zayas, Ena Medeiros, Rodrigo Mesa-Jurado, M. Moo-Culebro, Lízbeth Moseley, Cassandra Nielsen, Erik Phifer, Colin Pischke, Erin Schelly, Chelsea Selfa, Theresa Silva, Chelsea Souza, Tatiana Sweitz, Samuel and Vázquez-Navarrete, César 2021. Birds and Bioenergy within the Americas: A Cross-National, Social–Ecological Study of Ecosystem Service Tradeoffs. Land, Vol. 10, Issue. 3, p. 258.

Oliveira, Samuel L. Flaspohler, David J. Knowlton, Jessie L. Webster, Christopher R. and Wolfe, Jared D. 2021. Migratory bird community structure in oil palm (Elaies guineensis) plantations and native forest fragments in southern Mexico. Journal of Field Ornithology, Vol. 92, Issue. 1, p. 1.

Cardoso, Maira R. Matos, Fabio A.R. Almeida, Sara M. Silva, Larissa C. Cerqueira, Pablo V. Santos, Marcos P.D. and Edwards, David P. 2021. Connected riparian reserves retain high avian phylogenetic diversity in Amazonian oil palm. Biological Conservation, Vol. 259, Issue. , p. 109171.

Davies, Robert W. Edwards, David P. Medina-Uribe, Claudia A. Cárdenas-Bautista, Johann S. Haugaasen, Torbjørn Gilroy, James J. and Edwards, Felicity A. 2021. Replacing low-intensity cattle pasture with oil palm conserves dung beetle functional diversity when paired with forest protection. Journal of Environmental Management, Vol. 283, Issue. , p. 112009.

da Silva, Cleverton Ruiz-Esparza, Juan da Silva, Fabiana Oliveira de Azevedo, Cristiano Schetini and Ribeiro, Adauto de Souza 2021. Can guava monocultures (Psidium guajava L.) function as refuge for bird conservation?. Neotropical Biology and Conservation, Vol. 16, Issue. 4, p. 475.

Cruz-Elizalde, Raciel Pineda-López, Rubén Ramírez-Bautista, Aurelio and Berriozabal-Islas, Christian 2022. Diversity and composition of anuran communities in transformed landscapes in central Mexico. Community Ecology, Vol. 23, Issue. 1, p. 103.

Download full list

Article contents

The effects of oil palm plantations on the functional diversity of Amazonian birds

Abstract:

Keywords

Access options

References

LITERATURE CITED

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests