Limited carbon and biodiversity co‐benefits for tropical forest mammals and birds

Beaudrot, Lydia; Kroetz, Kailin; Álvarez-Loayza, Patricia; Amaral, Iêda Leão do; Breuer, Thomas; Fletcher, Christine; Jansen, Patrick A.; Kenfack, David; Lima, Marcela Guimarães Moreira; Marshall, Andrew R.; Martin, Emanuel H.; Ndoundou-Hockemba, Mireille; O’Brien, Timothy G.; Razafimahaimodison, Jean Claude; Romero‐Saltos, Hugo; Rovero, Francesco; Roy, Cisquet Hector; Sheil, Douglas; Silva, Carlos E. F.; Spironello, Wilson Roberto; Valencia, Renato; Zvoleff, Alex; Ahumada, Jorge; Andelman, Sandy J.

doi:10.1890/15-0935

Cited by 37 publications

(46 citation statements)

References 52 publications

(66 reference statements)

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“…Across a pantropical network of sites, Beaudrot et al (2016) and mammal occupancy in a certified forest reserve in Malaysian Borneo, despite adopting a comparable methodology to the present study. Contrasting findings may be attributed to spatial variability in hunting pressure.…”

Section: Contribution Of Redd+ To Biodiversity Conservationmentioning

confidence: 94%

“…While an increasing number of studies are recognising the importance of finescale assessments (e.g. Beaudrot et al, 2016;Magnago et al, 2015;Sollmann et al, 2017), most information on biodiversity co-benefits is derived from global-and national-scale studies that demonstrate overreliance on coarse-grained, secondary data sources. Carbon data are typically derived from global maps (e.g.…”

Section: Introductionmentioning

confidence: 99%

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High Carbon Stock forests provide co‐benefits for tropical biodiversity

Deere

Guillera‐Arroita

Baking

et al. 2017

Journal of Applied Ecology

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Abstract1. Carbon-based policies provide powerful opportunities to unite tropical forest conservation with climate change mitigation. However, their effectiveness in delivering biodiversity co-benefits is dependent on high levels of biodiversity being found in high carbon areas. Previous studies have focussed solely on the co-benefits associated with Reducing Emissions from Deforestation and forest Degradation (REDD+) over large spatial scales, with few empirically testing carbon-biodiversity correlations at management unit scales appropriate to decision-makers. Yet, in development frontiers, where most biodiversity and carbon loss occurs, carbon-based policies are increasingly driven by commodity certification schemes, which are applied at the concession level.2. Working in a typical human-modified landscape in Southeast Asia, we examined the biodiversity value of land prioritised via application of REDD+ or the High Carbon Stock (HCS) approach, the emerging land-use planning tool for oil palm certification. Carbon stocks were estimated via low-and high-resolution datasets derived from global or local-level biomass. Mammalian species richness was predicted using hierarchical Bayesian multispecies occupancy models of camera-trap data from forest and oil palm habitats. 3. At the community level, HCS forest supported comparable mammal diversity to control sites in continuous forest, while lower carbon strata exhibited reduced species occupancy.4. No association was found between species richness and carbon when the latter was estimated using coarse-resolution data. However, when using high-resolution, locally validated biomass data, diversity demonstrated positive relationships with carbon for threatened and disturbance-sensitive species, suggesting sensitivity of co-benefits to carbon data sources and the species considered.This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited. © 2017 The Authors. Journal of Applied Ecology published by John Wiley & Sons Ltd on behalf of British Ecological Society. | Journal of Applied EcologyDEERE Et al. | INTRODUCTIONAgricultural expansion has emerged as a pervasive threat to tropical forests and biodiversity (Wilcove, Giam, Edwards, Fisher, & Koh, 2013), and has been implicated in the loss of c. 150 million ha of tropical forest over the last three decades Hansen et al., 2013). A key driver of recent deforestation has been rising demand for cheap vegetable oil such as that from oil palm (Elaeis guineensis), which now covers 16 million ha across 43 countries, often at the expense of tropical forest (Pirker, Mosnier, Kraxner, Havlík, & Obersteiner, 2016).The potential economic and social benefits associated with oil palm (Potter, 2015) contrast with severe and well-documented ecological impacts. Conversion of forest to oil palm plantation results in major biodiversity decline, which disproportionately affects forest specialists and sp...

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Section: Contribution Of Redd+ To Biodiversity Conservationmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 99%

High Carbon Stock forests provide co‐benefits for tropical biodiversity

Deere

Guillera‐Arroita

Baking

et al. 2017

Journal of Applied Ecology

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“…The carbon-biodiversity relationship may also vary across taxonomic groups (Di Marco et al, 2018;Ferreira et al, 2018;Lecina-Diaz et al, 2018). Even in the tropics, most research to date has focused on either vertebrates (Beaudrot et al, 2016;Deere et al, 2018;Sollmann et al, 2017), or tree species richness only (Cavanaugh et al, 2014;Magnago et al, 2015;Sullivan et al, 2017), while research comparing the fine-scale carbon-biodiversity relationship across groups of organisms remains rare (Ferreira et al, 2018). This is understandable, given the inherent costs of collecting field-based data for multiple taxonomic groups (Bustamante et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

“…Finally, although the carbon-biodiversity relationship is often assumed to be linear (Beaudrot et al, 2016;Deere et al, 2018;Sullivan et al, 2017), thresholds could exist along the carbon stock gradient, meaning that a slight change in forest carbon stocks could cause disproportionate biodiversity loss (Evans et al, 2017;Sasaki, Furukawa, Iwasaki, Seto, & Mori, 2015). Such thresholds have been identified for a range of anthropogenic gradients (Li, Xu, Zheng, Taube, & Bai, 2017;Magnago et al, 2015;Sasaki et al, 2015), including carbon stocks in tropical forests (Ferreira et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Trade‐offs between carbon stocks and biodiversity in European temperate forests

Sabatini

Andrade

Paillet³

et al. 2018

Global Change Biology

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Policies to mitigate climate change and biodiversity loss often assume that protecting carbon‐rich forests provides co‐benefits in terms of biodiversity, due to the spatial congruence of carbon stocks and biodiversity at biogeographic scales. However, it remains unclear whether this holds at the scales relevant for management, and particularly large knowledge gaps exist for temperate forests and for taxa other than trees. We built a comprehensive dataset of Central European temperate forest structure and multi‐taxonomic diversity (beetles, birds, bryophytes, fungi, lichens, and plants) across 352 plots. We used Boosted Regression Trees (BRTs) to assess the relationship between above‐ground live carbon stocks and (a) taxon‐specific richness, (b) a unified multidiversity index. We used Threshold Indicator Taxa ANalysis to explore individual species’ responses to changing above‐ground carbon stocks and to detect change‐points in species composition along the carbon‐stock gradient. Our results reveal an overall weak and highly variable relationship between richness and carbon stock at the stand scale, both for individual taxonomic groups and for multidiversity. Similarly, the proportion of win‐win and trade‐off species (i.e., species favored or disadvantaged by increasing carbon stock, respectively) varied substantially across taxa. Win‐win species gradually replaced trade‐off species with increasing carbon, without clear thresholds along the above‐ground carbon gradient, suggesting that community‐level surrogates (e.g., richness) might fail to detect critical changes in biodiversity. Collectively, our analyses highlight that leveraging co‐benefits between carbon and biodiversity in temperate forest may require stand‐scale management that prioritizes either biodiversity or carbon in order to maximize co‐benefits at broader scales. Importantly, this contrasts with tropical forests, where climate and biodiversity objectives can be integrated at the stand scale, thus highlighting the need for context‐specificity when managing for multiple objectives. Accounting for critical change‐points of target taxa can help to deal with this specificity, by defining a safe operating space to manipulate carbon while avoiding biodiversity losses.

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“…In Brazilian rain forests the association was clear in human disturbed plots but not in old-growth forests that varied in carbon density [10]. Many studies report weak, non-existing or conflicting trends within the study areas [11][12][13][14][15].…”

Section: Introductionmentioning

confidence: 96%

Payments for adding ecosystem carbon are mostly beneficial to biodiversity

Larjavaara¹,

Davenport

Gangga

et al. 2019

Environ. Res. Lett.

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Biodiversity conservation is often considered to be an important co-benefit of REDD+and other mechanisms aiming to increase carbon in biomass and soil to mitigate climate change. This reasoning is based on the assumption that the level of biodiversity and ecosystem carbon are positively correlated. Firstly, however, studies have shown both positive and negative relationships. Secondly, incentives for additional ecosystem carbon do not trigger random or all potential changes in land-use, but often concentrate on one or a few specific changes that could have an opposite effect than the general trend indicates. Therefore, it is important to study biodiversity impacts of plausible measures to increase carbon. We obtained land-use scenarios on pathways to increase carbon based on 97 faceto-face interviews of local land-use experts in twelve landscapes in seven countries and five continents. We then conducted another set of face-to-face interviews with biodiversity experts yielding 2963 estimations concerning the value of land-use classes for 264 taxa of fauna and flora in these landscapes. We found positive carbon to biodiversity relationships in ten of the twelve landscapes. The biodiversity impacts of measures to increase carbon were positive in eleven of the twelve landscapes. Our results indicate that a random land-use change that increases biodiversity is also likely to increase carbon and vice versa.

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Limited carbon and biodiversity co‐benefits for tropical forest mammals and birds

Cited by 37 publications

References 52 publications

High Carbon Stock forests provide co‐benefits for tropical biodiversity

High Carbon Stock forests provide co‐benefits for tropical biodiversity

Trade‐offs between carbon stocks and biodiversity in European temperate forests

Payments for adding ecosystem carbon are mostly beneficial to biodiversity

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