Designing optimal human‐modified landscapes for forest biodiversity conservation

Agriculture and development transform forest ecosystems to human‐modified landscapes. Decades of research in ecology have generated myriad concepts for the appropriate management of these landscapes. Yet, these concepts are often contradictory and apply at different spatial scales, making the design...

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Veröffentlicht in:	Ecology letters 2020-09, Vol.23 (9), p.1404-1420
Hauptverfasser:	Arroyo‐Rodríguez, Víctor, Fahrig, Lenore, Tabarelli, Marcelo, Watling, James I., Tischendorf, Lutz, Benchimol, Maíra, Cazetta, Eliana, Faria, Deborah, Leal, Inara R., Melo, Felipe P. L., Morante‐Filho, Jose C., Santos, Bráulio A., Arasa‐Gisbert, Ricard, Arce‐Peña, Norma, Cervantes‐López, Martín J., Cudney‐Valenzuela, Sabine, Galán‐Acedo, Carmen, San‐José, Miriam, Vieira, Ima C. G., Slik, J.W. Ferry, Nowakowski, A. Justin, Tscharntke, Teja, Jordan, Ferenc
Format:	Artikel
Sprache:	eng
Schlagworte:	Agricultural development Agricultural ecosystems Agricultural management Biodiversity Biodiversity crisis Corridors extinction threshold Forest conservation Forest ecosystems Forest management Forests habitat amount hypothesis habitat fragmentation land sparing Landscape design Landscape preservation land‐use planning matrix quality Preservation Restoration strategies SLOSS debate Soil conservation Terrestrial ecosystems Tropical environments Wildlife Wildlife conservation Wildlife management
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creator	Arroyo‐Rodríguez, Víctor Fahrig, Lenore Tabarelli, Marcelo Watling, James I. Tischendorf, Lutz Benchimol, Maíra Cazetta, Eliana Faria, Deborah Leal, Inara R. Melo, Felipe P. L. Morante‐Filho, Jose C. Santos, Bráulio A. Arasa‐Gisbert, Ricard Arce‐Peña, Norma Cervantes‐López, Martín J. Cudney‐Valenzuela, Sabine Galán‐Acedo, Carmen San‐José, Miriam Vieira, Ima C. G. Slik, J.W. Ferry Nowakowski, A. Justin Tscharntke, Teja Jordan, Ferenc
description	Agriculture and development transform forest ecosystems to human‐modified landscapes. Decades of research in ecology have generated myriad concepts for the appropriate management of these landscapes. Yet, these concepts are often contradictory and apply at different spatial scales, making the design of biodiversity‐friendly landscapes challenging. Here, we combine concepts with empirical support to design optimal landscape scenarios for forest‐dwelling species. The supported concepts indicate that appropriately sized landscapes should contain ≥ 40% forest cover, although higher percentages are likely needed in the tropics. Forest cover should be configured with c. 10% in a very large forest patch, and the remaining 30% in many evenly dispersed smaller patches and semi‐natural treed elements (e.g. vegetation corridors). Importantly, the patches should be embedded in a high‐quality matrix. The proposed landscape scenarios represent an optimal compromise between delivery of goods and services to humans and preserving most forest wildlife, and can therefore guide forest preservation and restoration strategies. We review key concepts on species responses to landscape disturbances to prioritize management strategies for conservation of forest wildlife. We design optimal landscape scenarios for preserving most forest wildlife and promoting the delivery of goods and services to humans. The proposed scenarios can therefore guide forest preservation and restoration strategies in human‐modified landscapes.
doi_str_mv	10.1111/ele.13535
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L. ; Morante‐Filho, Jose C. ; Santos, Bráulio A. ; Arasa‐Gisbert, Ricard ; Arce‐Peña, Norma ; Cervantes‐López, Martín J. ; Cudney‐Valenzuela, Sabine ; Galán‐Acedo, Carmen ; San‐José, Miriam ; Vieira, Ima C. G. ; Slik, J.W. Ferry ; Nowakowski, A. Justin ; Tscharntke, Teja ; Jordan, Ferenc</creator><creatorcontrib>Arroyo‐Rodríguez, Víctor ; Fahrig, Lenore ; Tabarelli, Marcelo ; Watling, James I. ; Tischendorf, Lutz ; Benchimol, Maíra ; Cazetta, Eliana ; Faria, Deborah ; Leal, Inara R. ; Melo, Felipe P. L. ; Morante‐Filho, Jose C. ; Santos, Bráulio A. ; Arasa‐Gisbert, Ricard ; Arce‐Peña, Norma ; Cervantes‐López, Martín J. ; Cudney‐Valenzuela, Sabine ; Galán‐Acedo, Carmen ; San‐José, Miriam ; Vieira, Ima C. G. ; Slik, J.W. Ferry ; Nowakowski, A. Justin ; Tscharntke, Teja ; Jordan, Ferenc</creatorcontrib><description>Agriculture and development transform forest ecosystems to human‐modified landscapes. Decades of research in ecology have generated myriad concepts for the appropriate management of these landscapes. Yet, these concepts are often contradictory and apply at different spatial scales, making the design of biodiversity‐friendly landscapes challenging. Here, we combine concepts with empirical support to design optimal landscape scenarios for forest‐dwelling species. The supported concepts indicate that appropriately sized landscapes should contain ≥ 40% forest cover, although higher percentages are likely needed in the tropics. Forest cover should be configured with c. 10% in a very large forest patch, and the remaining 30% in many evenly dispersed smaller patches and semi‐natural treed elements (e.g. vegetation corridors). Importantly, the patches should be embedded in a high‐quality matrix. The proposed landscape scenarios represent an optimal compromise between delivery of goods and services to humans and preserving most forest wildlife, and can therefore guide forest preservation and restoration strategies. We review key concepts on species responses to landscape disturbances to prioritize management strategies for conservation of forest wildlife. We design optimal landscape scenarios for preserving most forest wildlife and promoting the delivery of goods and services to humans. 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L.</creatorcontrib><creatorcontrib>Morante‐Filho, Jose C.</creatorcontrib><creatorcontrib>Santos, Bráulio A.</creatorcontrib><creatorcontrib>Arasa‐Gisbert, Ricard</creatorcontrib><creatorcontrib>Arce‐Peña, Norma</creatorcontrib><creatorcontrib>Cervantes‐López, Martín J.</creatorcontrib><creatorcontrib>Cudney‐Valenzuela, Sabine</creatorcontrib><creatorcontrib>Galán‐Acedo, Carmen</creatorcontrib><creatorcontrib>San‐José, Miriam</creatorcontrib><creatorcontrib>Vieira, Ima C. G.</creatorcontrib><creatorcontrib>Slik, J.W. Ferry</creatorcontrib><creatorcontrib>Nowakowski, A. Justin</creatorcontrib><creatorcontrib>Tscharntke, Teja</creatorcontrib><creatorcontrib>Jordan, Ferenc</creatorcontrib><title>Designing optimal human‐modified landscapes for forest biodiversity conservation</title><title>Ecology letters</title><description>Agriculture and development transform forest ecosystems to human‐modified landscapes. Decades of research in ecology have generated myriad concepts for the appropriate management of these landscapes. Yet, these concepts are often contradictory and apply at different spatial scales, making the design of biodiversity‐friendly landscapes challenging. Here, we combine concepts with empirical support to design optimal landscape scenarios for forest‐dwelling species. The supported concepts indicate that appropriately sized landscapes should contain ≥ 40% forest cover, although higher percentages are likely needed in the tropics. Forest cover should be configured with c. 10% in a very large forest patch, and the remaining 30% in many evenly dispersed smaller patches and semi‐natural treed elements (e.g. vegetation corridors). Importantly, the patches should be embedded in a high‐quality matrix. 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The proposed scenarios can therefore guide forest preservation and restoration strategies in human‐modified landscapes.</description><subject>Agricultural development</subject><subject>Agricultural ecosystems</subject><subject>Agricultural management</subject><subject>Biodiversity</subject><subject>Biodiversity crisis</subject><subject>Corridors</subject><subject>extinction threshold</subject><subject>Forest conservation</subject><subject>Forest ecosystems</subject><subject>Forest management</subject><subject>Forests</subject><subject>habitat amount hypothesis</subject><subject>habitat fragmentation</subject><subject>land sparing</subject><subject>Landscape design</subject><subject>Landscape preservation</subject><subject>land‐use planning</subject><subject>matrix quality</subject><subject>Preservation</subject><subject>Restoration strategies</subject><subject>SLOSS debate</subject><subject>Soil conservation</subject><subject>Terrestrial ecosystems</subject><subject>Tropical environments</subject><subject>Wildlife</subject><subject>Wildlife conservation</subject><subject>Wildlife management</subject><issn>1461-023X</issn><issn>1461-0248</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2020</creationdate><recordtype>article</recordtype><recordid>eNp1kMtKAzEUhoMoWKsL32DAjS6mzW0uWUqtFygIouAuZHKpKTOTMZlWuvMRfEafxNQRF4KBQw6c7xw-fgBOEZyg-Ka61hNEMpLtgRGiOUohpuX-b0-eD8FRCCsIEWYFGoGHKx3ssrXtMnFdbxtRJy_rRrSf7x-NU9ZYrZJatCpI0emQGOd3pUOfVDbON9oH228T6dqg_Ub01rXH4MCIOuiTn38Mnq7nj7PbdHF_cze7XKSSsDxLs9IoqTTCmBpscMkwZJkQBpKizElOlNQYE0pQhQqCKVM5NFQXxigmMakqMgbnw93Ou9d1VOKNDVLXUVe7deCYIgohI6yM6NkfdOXWvo12kSIoL1nUiNTFQEnvQvDa8M7HRPyWI8h36fKYLv9ON7LTgX2ztd7-D_L5Yj5sfAHBVXy2</recordid><startdate>202009</startdate><enddate>202009</enddate><creator>Arroyo‐Rodríguez, Víctor</creator><creator>Fahrig, Lenore</creator><creator>Tabarelli, Marcelo</creator><creator>Watling, James I.</creator><creator>Tischendorf, Lutz</creator><creator>Benchimol, Maíra</creator><creator>Cazetta, Eliana</creator><creator>Faria, Deborah</creator><creator>Leal, Inara R.</creator><creator>Melo, Felipe P. 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Yet, these concepts are often contradictory and apply at different spatial scales, making the design of biodiversity‐friendly landscapes challenging. Here, we combine concepts with empirical support to design optimal landscape scenarios for forest‐dwelling species. The supported concepts indicate that appropriately sized landscapes should contain ≥ 40% forest cover, although higher percentages are likely needed in the tropics. Forest cover should be configured with c. 10% in a very large forest patch, and the remaining 30% in many evenly dispersed smaller patches and semi‐natural treed elements (e.g. vegetation corridors). Importantly, the patches should be embedded in a high‐quality matrix. The proposed landscape scenarios represent an optimal compromise between delivery of goods and services to humans and preserving most forest wildlife, and can therefore guide forest preservation and restoration strategies. We review key concepts on species responses to landscape disturbances to prioritize management strategies for conservation of forest wildlife. We design optimal landscape scenarios for preserving most forest wildlife and promoting the delivery of goods and services to humans. 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subjects	Agricultural development Agricultural ecosystems Agricultural management Biodiversity Biodiversity crisis Corridors extinction threshold Forest conservation Forest ecosystems Forest management Forests habitat amount hypothesis habitat fragmentation land sparing Landscape design Landscape preservation land‐use planning matrix quality Preservation Restoration strategies SLOSS debate Soil conservation Terrestrial ecosystems Tropical environments Wildlife Wildlife conservation Wildlife management
title	Designing optimal human‐modified landscapes for forest biodiversity conservation
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