Hostname: page-component-848d4c4894-4hhp2 Total loading time: 0 Render date: 2024-05-18T10:15:09.744Z Has data issue: false hasContentIssue false
  • English
  • Français

Projecting forest cover in Madagascar's protected areas to 2050 and its implications for lemur conservation

Published online by Cambridge University Press:  10 November 2023

Serge C. Rafanoharana Open the ORCID record for Serge C. Rafanoharana [Opens in a new window] ,
F. Ollier D. Andrianambinina Open the ORCID record for F. Ollier D. Andrianambinina [Opens in a new window] ,
H. Andry Rasamuel Open the ORCID record for H. Andry Rasamuel [Opens in a new window] ,
Patrick O. Waeber Open the ORCID record for Patrick O. Waeber [Opens in a new window] ,
Lucienne Wilmé Open the ORCID record for Lucienne Wilmé [Opens in a new window]  and
Jörg U. Ganzhorn Open the ORCID record for Jörg U. Ganzhorn [Opens in a new window]
Serge C. Rafanoharana
Affiliation:
World Resources Institute Africa, Antananarivo, Madagascar
F. Ollier D. Andrianambinina
Affiliation:
Madagascar National Parks, Antananarivo, Madagascar
H. Andry Rasamuel
Affiliation:
World Resources Institute Africa, Antananarivo, Madagascar
Patrick O. Waeber
Affiliation:
Department of Agricultural, Forest and Food Sciences HAFL, Bern University of Applied Sciences, Zollikofen, Switzerland Department of Environmental Systems Science, Swiss Federal Institute of Technology (ETH), Zürich, Switzerland
Lucienne Wilmé
Affiliation:
World Resources Institute Africa, Antananarivo, Madagascar Madagascar Research and Conservation Program, Missouri Botanical Garden, Antananarivo, Madagascar
Jörg U. Ganzhorn*
Affiliation:
Universität Hamburg, Hamburg, Germany IUCN Species Survival Commission Primate Specialist Group
*
*Corresponding author, joerg.ganzhorn@uni-hamburg.de
Rights & Permissions [Opens in a new window]

Abstract

Predicting future conservation needs can help inform conservation management but is subject to uncertainty. We measured deforestation rates during 2015–2017 for 114 protected areas in Madagascar, linked deforestation to the status of protection according to IUCN categories I–VI, used recent deforestation rates to extrapolate forest cover over 2017–2050 and linked the size of forest blocks to the projected persistence of lemur subpopulations. In the six IUCN categories for protected areas in Madagascar the median size of forest blocks is 9–37 km2 and median annual deforestation rates range from 0.02% in the single IUCN category III site to 0.19% in category II and 1.95% in category VI sites. In 2017, 40% of all forest blocks within protected areas were < 10 km2, and this is projected to increase to 45% in 2050. Apart from these small forest fragments, the modal site of forest blocks was 160–320 km2 in 2017, and this is projected to decrease to 80–160 km2 in 2050. The range of > 50% of all lemur species exclusively contains forest blocks of < 10 km2. The modal size of forest blocks > 10 km2 is predicted to remain at 120 km2 until 2050. Although uncertainty remains, these analyses provide hope that forest blocks within the protected areas of Madagascar will remain large enough to maintain lemur subpopulations for most species until 2050. This should allow sufficient time for the implementation of effective conservation measures.

Keywords

Biodiversitydeforestationforest changeIUCN protected area categorylemurMadagascarprimate conservationviable population
Type
Article
Information
Oryx , Volume 58 , Issue 2 , March 2024 , pp. 155 - 163
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of Fauna & Flora International

Introduction

To counteract future biodiversity loss, Madagascar has quadrupled the area of its protected area system since 2003. Although this increase is remarkable, it remains uncertain whether current conservation efforts will be able to save the unique biodiversity of Madagascar (Gardner et al., Reference Gardner, Nicoll, Birkinshaw, Harris, Lewis, Rakotomalala and Ratsifandrihamanana2018). Conservation assessments of terrestrial ecosystems mostly distinguish between forest and non-forest areas. This binary typology of forest vs non-forest is overly simplistic for classifying Malagasy terrestrial vegetation (e.g. Lowry et al., Reference Lowry II, Schatz, Phillipson, Goodman and Patterson1997; Moat & Smith, Reference Moat and Smith2007), but the majority of the endemic vertebrate fauna of Madagascar is forest dependent, and the dichotomous classification of forest vs non-forest is often used as a proxy for conservation measures (Goodman et al., Reference Goodman, Raherilalao and Wohlhauser2018; Rafanoharana et al., Reference Rafanoharana, Andrianambinina, Rasamuel, Rakotoarijaona, Waeber, Ganzhorn and Wilmé2023). Although the original protected areas belonging to IUCN categories I–III seem to have provided reasonable protection over the last few decades (Goodman et al., Reference Goodman, Raherilalao and Wohlhauser2018), most of the protected areas added recently are of IUCN categories IV–VI. Categories V and VI assign governance responsibilities to communities and allow multiple uses of the areas, such as supposedly sustainable extraction of natural resources to secure traditional livelihoods (Table 1). As this is a new approach for Madagascar, the protected areas under the responsibility of communities and/or NGOs often lack crucial resources and capacities and thus seem to be less effective for biodiversity conservation than protected areas of IUCN categories I–III (Gardner et al., Reference Gardner, Nicoll, Birkinshaw, Harris, Lewis, Rakotomalala and Ratsifandrihamanana2018; Rafanoharana et al., Reference Rafanoharana, Andrianambinina, Rasamuel, Rakotoarijaona, Ganzhorn, Waeber and Wilmé2021; Stoudmann et al., Reference Stoudmann, Savilaakso, Waeber, Wilmé, Garcia, Byrne and Adams2023). Thus, it is unclear what role these new protected areas could have in species conservation and how the biodiversity of Madagascar will be affected by ongoing deforestation (Vieilledent et al., Reference Vieilledent, Grinand, Rakotomalala, Ranaivosoa, Rakotoarijaona and Allnutt2018).

Table 1 The protected area categories system advocated by IUCN since 1994 (Phillips, Reference Phillips2004).

Given that a large proportion of the biodiversity of Madagascar remains unknown, species-based conservation management is mostly based on conspicuous taxa, such as higher plants or vertebrates, which can also be considered umbrella species (Kremen et al., Reference Kremen, Cameron, Moilanen, Phillips, Thomas and Beentje2008; Miller & Morgan, Reference Miller and Morgan2011; Vieilledent et al., Reference Vieilledent, Cornu, Cuní Sanchez, Leong Pock-Tsy and Danthu2013; Jenkins et al., Reference Jenkins, Tognelli, Bowles, Cox, Brown and Chan2014; Schwitzer et al., Reference Schwitzer, Mittermeier, Johnson, Donati, Irwin and Peacock2014; Tagliari et al., Reference Tagliari, Danthu, Leong Pock Tsy, Cornu, Lenoir and Carvalho-Rocha2021). Because of their close relatedness to people and their precarious conservation situation, primates in general and lemurs of Madagascar in particular are regularly assessed (Schwitzer et al., Reference Schwitzer, Mittermeier, Johnson, Donati, Irwin and Peacock2014; Estrada et al., Reference Estrada, Garber, Rylands, Roos, Fernandez-Duque and Di Fiore2017). Although assessing the current status of species is difficult, projecting the fate of species into the future adds another level of uncertainty. For lemurs this projection has been attempted in the context of overall deforestation, fragmentation and climate change (Brown & Yoder, Reference Brown and Yoder2015; Morelli et al., Reference Morelli, Smith, Mancini, Balko, Borgerson and Dolch2020; Vieilledent et al., Reference Vieilledent, Allnutt, Grinand, Pedrono, Rakotoarijaona and Razafimpahanana2021; Steffens et al., Reference Steffens, Ramsay, Malabet, Lehman and Goodman2022).

Here we use an analysis of the extent of forest areas and deforestation rates of all protected areas of Madagascar during 2015–2017 as a proxy for a formal assessment of lemur populations and to project their development within protected areas for 2017–2050. Specifically, we seek to answer the following questions: (1) How did forest cover change in the protected areas of Madagascar during 2015–2017? (2) Did the forest cover change differently in protected areas of different IUCN categories? (3) Was the change in forest cover related to the size of the forest? From the answers to these three questions we project the size of forest blocks for 2017–2050, assuming that the current deforestation rate of each protected area will remain constant. (4) Taking the size of forest blocks as a proxy for the relative number of individuals per forest block, we ask: how do conservation assessments based on the reduction of the size of subpopulations change when based on projections of the total size of protected areas in 2050 and of the forest areas when considering distinct forest blocks within protected areas?

Methods

Estimating forest cover

The approach used to assess forest cover has been described previously (Rafanoharana et al., Reference Rafanoharana, Andrianambinina, Rasamuel, Rakotoarijaona, Ganzhorn, Waeber and Wilmé2021) and is summarized here only briefly. Within a larger project to estimate forest change for all of the protected areas of Madagascar, we analysed 114 terrestrial protected areas, considering humid forest, dry western forest and south-western dry and spiny forests and thickets. We obtained the raw shapefile data from the protected area management system of the Ministry of Environment and Sustainable Development of Madagascar based on the legal document of creation. From our long-term historical dataset covering 1990–2017 we used time series forest cover data for the years 2015 and 2017 (based on those from Vieilledent et al., Reference Vieilledent, Grinand, Rakotomalala, Ranaivosoa, Rakotoarijaona and Allnutt2018), which were the result of a combination of the 2000 forest cover map and annual tree cover loss maps at 30-m spatial resolution. We restricted the analyses to these 2 years because most of the new protected areas of IUCN categories IV and V were formally established only in 2015. The forest data used here have some biases because the remote sensing tools currently applied tend to underestimate forest cover in dry forest and overestimate it in humid forest (Rafanoharana et al., Reference Rafanoharana, Andrianambinina, Rasamuel, Rakotoarijaona, Waeber, Ganzhorn and Wilmé2023). Therefore, the data for the dry forests used here should be regarded as minimum values, and forest cover changes are likely to be higher.

Almost 20% of the protected areas (22/111) comprise several forest blocks; a block is defined as any non-contiguous shape within a protected area. These blocks are separated by a non-forest matrix, and thus the forested part of a protected area is smaller than the total surface of the area.

We did not consider the protected areas of Bemaraha, Beza-Mahafaly and Zahamena because the delimitation of blocks was unclear at the time of analysis. These sites experienced little deforestation during 2015–2017 (Bemaraha: 95,909 to 95,534 ha; Beza-Mahafaly: 521.26 to 521.16 ha; Zahamena: 69,008 to 68,792 ha). Their exclusion does not change the general conclusions of the analyses.

Areas (either the protected area as a whole or the exact size of the different non-contiguous forest blocks within any given protected area) were assigned to size classes of 0–9.99 km2, 10–19.99 km2, 20–39.99 km2, 40–79.99 km2, etc., doubling from one class to the next to ≥ 2,559 km2 (Fig. 1). We assume that all forest areas provide suitable habitat for all lemurs occurring in the region. This is improbable, and so this approach overestimates the area inhabited by lemurs.

Fig. 1 Size distribution of protected areas in Madagascar (a) as a whole and (b) as forest blocks in 2017 and projected to 2050 based on current deforestation rates (Table 2). Size classes double from one class to the next. Values on the x-axes are the midpoints in each category (e.g. 5 km2 represents blocks of 0–9.99 km2, 15 km2 represents blocks of 10–19.99 km2, etc.).

Projecting forest loss during 2017–2050

Forest loss until 2050 was estimated using the per cent of annual forest loss during 2015–2017 for each protected area separately. To check whether this period is representative of long-term deforestation rates we compared the annual rate during 2015–2017 with the deforestation rates over 5-year intervals during the previous 25 years. We included only the IUCN category I–III areas. We did not consider protected areas that changed in size during 1990–2015. The median annual deforestation rate for the remaining 45 areas (all of IUCN categories I–III) was 0.06% during 1990–2000, 0.03% during 2000–2005, 0.04% during 2005–2010, 0.14% during 2010–2015 and 0.18% during 2015–2017. Thus, the deforestation rate during 2015–2017 was higher than in previous years. The trends in deforestation rates in the protected areas over time match the deforestation trends for all of the forests of Madagascar (including forest outside protected areas), although our deforestation rates within IUCN category I–III protected areas were approximately an order of magnitude lower than the deforestation rates reported for Madagascar as a whole (Vieilledent et al., Reference Vieilledent, Grinand, Rakotomalala, Ranaivosoa, Rakotoarijaona and Allnutt2018). For the projections of future degradation, we assumed the deforestation rates during 2015–2017 remain constant for each protected area until 2050. If the deforestation rates during 2015–2017 were exceptionally high, their application to the projection might overestimate future deforestation rates. If deforestation rates increase over time, as indicated by the trend for 2000–2017, the application of constant deforestation rates until 2050 would underestimate forest loss. We then calculated the forest loss of each protected area for the 33 years of 2017–2050 using compound computation of interest as follows: Forest size in 2050 = Forest size in 2017 × ((100 – mean of annual forest loss in per cent)/100)33.

Lemur subpopulations

As of 2018, 107 lemur species are recognized on the IUCN Red List. This number is likely to change because of revisions, the use of new taxonomic methods and/or new discoveries (Tattersall & Cuozzo, Reference Tattersall, Cuozzo, Goodman, Raherilalao and Wohlauser2018; Hending et al., Reference Hending, Randrianarison, Andriamavosoloarisoa, Ranohatra-Hending, McGabe and Cotton2022; Poelstra et al., Reference Poelstra, Montero, Lüdemann, Yang, Rakotondranary and Hohenlohe2022), but the principal conclusions of our analyses should remain valid. We took the occurrence of lemur species from the Noe4D biodiversity database (Wilmé et al., Reference Wilmé, Goodman and Ganzhorn2006; Waeber et al., Reference Waeber, Rafanoharana, Rasamuel, Wilmé, Bakar and Suratman2020), supplemented by Goodman et al. (Reference Goodman, Raherilalao and Wohlhauser2018). Given the localized occurrence of some lemur species (Wilmé et al., Reference Wilmé, Goodman and Ganzhorn2006, Reference Wilmé, RavokatraI, Dolch, Schuurman, Mathieu and Schuetz2012; Mittermeier et al., Reference Mittermeier, Louis, Richardson, Schwitzer, Langrand and Rylands2010), we did not consider species to be present in any given protected area on the basis of their geographical range but only when they had been reported to occur in the protected area. Lemur occurrences are not available for individual forest blocks but rather for the protected area as a whole. Although it is unlikely that all lemur species listed as occurring within any given protected area occur in all of its forest blocks, in the absence of more detailed data we assume this. This results in an overestimate of the number of lemur subpopulations.

We did not consider taxa that were not identified to species. This approach eliminated some representatives of the genera Avahi, Cheirogaleus, Hapalemur, Lepilemur, Microcebus, Mirza and Phaner from some sites. We did not include Hapalemur alaotrensis in the analyses as this species is restricted to reed habitat.

We excluded protected areas without lemurs or for which inventories are not available. These are Ambohidray (1,241 ha, no information on lemur occurrences), Ampanangandehibe-Behasina (580 ha, no forest), Andreba (39 ha, no forest), Ibity (6,137 ha, no forest), Mahialambo (304 ha, no forest), Maningozy (5,973 ha, 773 ha of forest in 2017), Manjakatompo Ankaratra (8,131 ha, 815 ha of forest in 2017, no lemur species recorded by the Mission zoologique Franco-Anglo-Américaine in 1929 or during a biodiversity inventory in 1996; Goodman et al., Reference Goodman, Rakotondravony, Schatz and Wilmé1996).

Results

Forest cover and loss during 2015–2017

In 2017 the 102 protected areas considered ranged from 0.97 to 4,194.12 km2, with a median size of 236.29 km2 and an interquartile range of 43.25–750.49 km2. Most protected areas were 320–640 km2 (Fig. 1). At this time there were 170 forest blocks within the protected areas (Fig. 1). The median size of these blocks was 21.92 km2, with an interquartile range of 4.57–172.27 km2.

With a median area of 37.45 km2, IUCN categories I–III protected areas were larger than the IUCN categories IV–VI protected areas, whose median areas were 9.13–28.21 km2 (Table 2). The former comprised 47.3% of the whole protected forest area.

Table 2 Number and size of forest blocks and total forest area in 2017, and deforestation per year during 2015–2017 in the protected areas of Madagascar (Fig. 1), by IUCN category, and projections of per cent forest loss during 2017–2050 and total forest area in 2050.

1 Values are medians and quartiles (Q25–median–Q75).

The annual deforestation rate during 2015–2017 ranged between no measurable change to a decrease of 13.57% per year (Table 2). It differed significantly depending on IUCN category, with protected areas of IUCN categories IV–VI having higher deforestation rates than those of IUCN category II (Kruskal–Wallis ANOVA without protected areas of categories I and III, removed because of small sample size: H = 19.07, P < 0.001, df = 3). Annual deforestation in IUCN category II protected areas differed significantly from those in IUCN categories V and VI (Mann–Whitney U: P ≤ 0.01, Bonferroni corrected). IUCN category I protected areas are Betampona and Tsaratanana, and the IUCN category III protected area is Alandraza-Analavelo.

Deforestation rate was not related to the size of the forest blocks within the protected areas (Spearman's correlation: rs = 0.12, P > 0.05, N = 170).

Projecting forest loss to 2050

Assuming constant deforestation rates in all protected areas, the protected forest is projected to decrease by 9,306 km2 during 2017–2050 (c. 25% of the total forest area). The decrease in IUCN categories I–III protected areas is projected to be 16.88% during 2017–2050, and 21.31–39.16% in the other IUCN categories.

In 2017, 68 (40%) of the 170 forest blocks were < 10 km2. Apart from these smallest blocks, the largest number of forest blocks were 160–320 km2 (Fig. 1). By 2050, these figures are projected to have changed to 76 (45%) forest blocks < 10 km2, with the mode projected to be 80–160 km2.

Perspectives for lemur species

Two lemur species are not known to occur in any protected area. Microcebus boraha is restricted to Île Sainte Marie, an island off the east coast of Madagascar that lacks any protected areas (Reuter et al., Reference Reuter, Mittermeier and Schwitzer2020). The distribution of Lepilemur grewcockorum falls between Bongolava Reserve, 30 km south-south-east of the reported occurrence of this species, and the Réserve Spéciale Bora, 57 km to the north-east (Louis et al., Reference Louis, Bailey, Sefczek, Raharivololona, Schwitzer and Ratsimbazafy2020). The remaining 105 of the 107 recognized lemur species are recorded in at least one protected area, although the representation of IUCN categories for protected areas varies widely between species (Supplementary Table 1). Thirty species are known only from a single protected area, and > 50% of them occur in no more than four protected areas (Fig. 2). On average, by 2050 the forested area currently inhabited by lemurs is projected to decrease by 19% (Supplementary Table 2).

Fig. 2 Occurrence of lemur species in the protected areas of Madagascar as of 2017. The numbers on the x-axis represent the number of protected areas where any given lemur species has been recorded (e.g. 30 species are known from a single protected area and 10 species from two areas).

Lemur subpopulations in protected areas of different sizes

If all lemur species were present in all forest blocks of any given protected area (which is unlikely), the protected areas would be home to 1,299 subpopulations of the various lemur species (Supplementary Table 3). Of these 1,299 mostly isolated subpopulations, 471 (36.3%) would occur in forest blocks < 10 km2 (Fig. 3).

Fig. 3 Lemur subpopulations occurring in different-sized forest blocks in Madagascar in 2017 and 2050, assuming the same deforestation rates as recorded during 2015–2017. Size classes double from one class to the next. Values on the x-axis are the midpoints in each category (e.g. 5 km2 represents blocks of 0–9.99 km2, 15 km2 represents blocks of 10–19.99 km2, etc.).

Change in protected forest areas for lemur subpopulations until 2050

The projection of the 2015–2017 deforestation rates to 2050 is restricted to analysis at the level of forest blocks. The number of lemur subpopulations in forest blocks of the smallest size of up to 10 km2 would increase by c. 10% (from 471 to 519). The mode remains at 80–160 km2. According to this analysis, the sizes of lemur subpopulations would be reduced, but in 2050 most species would still remain within the size classes of forest blocks they occupied in 2017 (Supplementary Table 3).

Discussion

Application of the forest analysis to lemur occurrences illustrates the importance of obtaining more detailed information regarding the actual situation of protected areas for conservation evaluations. If the total size of protected areas was used to estimate the size of lemur subpopulations, most species would be assumed to occur in areas of 320–640 km2. However, when one considers the forested areas and fragmentation of forest areas, the majority of forest blocks within protected areas are < 10 km2. Any species occurring in only one of these forest blocks would be categorized as Critically Endangered according to the B2 criterion of the IUCN Red List threat categories (area of occupancy < 10 km2; IUCN, 2001). When not considering these smallest forest fragments, the mode of forest blocks is predicted to decline from 320–640 km2 for protected areas as a whole to 80–160 km2. As these isolated forest blocks comprise the actual forests within the protected areas, they reflect a decline in area for continuous subpopulations to c. 25% of their size in 2017. This reduction in size is relevant not only for subpopulations but also for communities as a whole. Species–area relationships predict a continuous decline in species numbers with decreasing area of suitable habitat (MacArthur & Wilson, Reference MacArthur and Wilson1967). The slope of this relationship varies widely amongst taxa and ecosystems (Brown & Lomolino, Reference Brown and Lomolino1998), and, apart from analyses on national and continental scales (Brown, Reference Brown1995; Cowlishaw, Reference Cowlishaw1999), most studies address this issue using forest fragments of much smaller size and thus do not allow predictions of the viability of lemur subpopulations in relation to the size of larger forest blocks (Harcourt, Reference Harcourt2002; Fahrig, Reference Fahrig2017; Kling et al., Reference Kling, Yaeger and Wright2020; Strier, Reference Strier2021). However, a fourfold difference in size from a mean area of c. 480 to c. 120 km2 would be associated with a change in community processes and substantial extinction debt (i.e. a delayed extinction of species until the number of species associated with a certain area is reached again according to the species–area relationships deriving from the biogeography of the island; MacArthur & Wilson, Reference MacArthur and Wilson1967). In the long term, the reduction in size of the forest blocks would result in a reduction of individuals per subpopulation, possibly with subsequent extinction and finally reduced species numbers per forest block. As data on the viability of different-sized lemur populations are lacking (Ganzhorn et al., Reference Ganzhorn, Goodman, Ramanamanjato, Ralison, Rakotondravony and Rakotosamimanana2000), the predicted reduced forest block size adds a new conceptional dimension and challenge to conservation planning (Kuussaari et al., Reference Kuussaari, Bommarco, Heikkinen, Helm, Krauss and Lindborg2009; Laurance et al., Reference Laurance, Useche, Rendeiro, Kalka, Bradshaw and Sloan2012).

Although lemur subpopulations suffer significantly from large-scale forest destruction and hunting (Schwitzer et al., Reference Schwitzer, Mittermeier, Johnson, Donati, Irwin and Peacock2014; Randriamady et al., Reference Randriamady, Park, Andrianarimanana, Berobia and Golden2021; Borgerson et al., Reference Borgerson, Johnson, Hall, Brown, Narváez-Torres and Rasolofoniaina2022; Kappeler et al., Reference Kappeler, Markolf, Rasoloarison, Fichtel and Durbin2022), fragmentation effects do not yet seem to be significant at the scale of forest blocks > 10 km2 (Steffens et al., Reference Steffens, Ramsay, Malabet, Lehman and Goodman2022). Even the species with the largest body mass and thus the lowest population densities and numbers of individuals seem to maintain viable populations in relatively small forest blocks if human pressure is controlled (Jolly et al., Reference Jolly, Dobson, Rasamimanana, Walker, O'Connor, Solberg and Perel2002). Although genetic deficits because of genetic erosion or inbreeding could become relevant (Montero et al., Reference Montero, Refaly, Ramanamanjato, Randriatafika, Rakotondranary and Wilhelm2019), most of these forest blocks are projected to persist up to and beyond 2050, providing a time buffer of more than one human generation for establishing effective conservation measures.

Although the present analysis provides some hope for the persistence of the forest ecosystems of Madagascar within the protected area system, our analyses are based on the assumption that deforestation rates would not change for the next few decades. If the trend of increasing deforestation rates continues as it did during 2000–2017, we would expect an annual deforestation rate of c. 0.7% in 2050 even in the IUCN category I–IV protected areas (trends could not be calculated for the IUCN categories V and VI protected areas because they were established only in 2015 and long-term deforestation rates were not available). In addition to these possible assumption errors, there is substantial error in defining forest vs non-forest pixels when applying standard remote sensing methods, especially for dry and spiny forests (Rafanoharana et al., Reference Rafanoharana, Andrianambinina, Rasamuel, Rakotoarijaona, Waeber, Ganzhorn and Wilmé2023). It remains unknown whether these trends in deforestation rates would persist once the information derived from remote sensing has been adapted. Using a similar approach, Vieilledent et al. (Reference Vieilledent, Allnutt, Grinand, Pedrono, Razafimpahanana and Rakotoarijaona2020) applied a constant annual deforestation rate of 100,000 ha during 2010–2050 (corresponding to 1.2% on the basis of the forest cover in 2010) for all of the forests of Madagascar in relation to protection status and environmental and socio-economic factors (Fig. 4). At the time of their analyses, IUCN categories V and VI protected areas had not yet been established, and thus their effect could not have been considered.

Fig. 4 (a) Forest cover in Madagascar in 2017, (b) projection of deforestation (from Vieilledent et al., Reference Vieilledent, Allnutt, Grinand, Pedrono, Rakotoarijaona and Razafimpahanana2021) assuming a constant deforestation rate of 100,000 ha/year (corresponding to 1.2% on the basis of the forest cover of 2010) from 2010 to 2050, and (c) the locations of protected areas, by IUCN category (Table 1). NA, not assigned to an IUCN category. (Readers of the printed journal are referred to the online article for a colour version of this figure.)

Apart from methodological uncertainties, the relatively low deforestation rates observed until 2017 could change as a result of stochastic events. Historically, deforestation rates have increased during times of political crisis (Zinner et al., Reference Zinner, Wygoda, Razafimanantsoa, Rasoloarison, Andrianandrasana and Ganzhorn2014). A diversity of circumstances, such as the Covid-19 pandemic (Eklund et al., Reference Eklund, Jones, Räsänen, Geldmann, Jokinen and Pellegrini2022), has the potential to change deforestation rates, although protected area management in Madagascar has shown a high capacity to counteract these expected negative impacts on protected areas (Andrianambinina et al., Reference Andrianambinina, Waeber, Schuurman, Lowry and Wilmé2022). Nevertheless, there have been unusual records of forest destruction, such as the reported areas of forest burnt after periods with low rainfall in October 2022 at Baie de Baly (9,263 ha), Tsingy de Namoroka (785 ha), Zombitse Vohibasia (1,242 ha), Ankarafantsika (7,341 ha), Manongarivo (733 ha) and Sahamalaza (581 ha), although these primarily concerned degraded forests. It is also of note that the new protected areas of IUCN categories V and VI have 5–10 times higher deforestation rates than those of categories I–III. The reasons for this and possible countermeasures to be taken to improve the situation were outlined by Gardner et al. (Reference Gardner, Nicoll, Birkinshaw, Harris, Lewis, Rakotomalala and Ratsifandrihamanana2018).

Conclusion

Our analyses support the notion that the new protected areas in Madagascar belonging to IUCN categories V and VI are not as effective for conserving subpopulations of lemur species as the previously existing protected areas. Many of these new protected areas are under multi-use management by local communities and NGOs, allowing sustainable extraction of natural resources. In many cases, socio-economic conditions, lack of knowledge or lack of resources for management prohibit sustainable utilization of these forests. The challenges of combining extractive resource management with conservation goals might be too complex to be left to local communities or NGOs with limited means (Gardner et al., Reference Gardner, Nicoll, Birkinshaw, Harris, Lewis, Rakotomalala and Ratsifandrihamanana2018; Stoudmann et al., Reference Stoudmann, Savilaakso, Waeber, Wilmé, Garcia, Byrne and Adams2023). More positively, our results provide hope that sufficient forest will remain within protected areas for the next 25+ years to maintain the lemur species currently present there. However, although lemurs can be considered umbrella species for other forest-dependent taxa, conclusions based on lemur occurrences alone do not necessarily apply to the other higher taxa of Madagascar (Kremen et al., Reference Kremen, Cameron, Moilanen, Phillips, Thomas and Beentje2008).

For the future of the forests and lemurs of Madagascar, conservation initiatives outside protected areas need to be effective by 2050. Amongst these initiatives, agroforestry and ecological restoration concepts for the reforestation or rehabilitation of degraded land are promising (Holloway, Reference Holloway, Goodman and Benstead2003; Birkinshaw et al., Reference Birkinshaw, Lowry II, Raharimampionona and Aronson2013; Hending et al., Reference Hending, Andrianiaina, Rakotomalala and Cotton2018; Donati et al., Reference Donati, Ramanamanjato, Blum, Flury and Ganzhorn2021). These approaches could include planting tree species used by lemurs (Steffens, Reference Steffens2020), planting species of use for people and the endemic biota of Madagascar alike (Konersmann et al., Reference Konersmann, Noromiarilanto, Ratovonamana, Brinkmann, Jensen and Kobbe2022), complementary planting of native and introduced commercial species (Ganzhorn, Reference Ganzhorn1987; Gérard et al., Reference Gérard, Ganzhorn, Kull and Carrière2015; Lavialle et al., Reference Lavialle, Carrière, Miandrimanana, Tilahimena, Birkinshaw and Aronson2015) and stratified planting of multiple-use trees and crops that reduce pressure on forest resources (Manjaribe et al., Reference Manjaribe, Frasier, Rakouth and Louis2013). These activities would extend suitable habitats for forest-dependent species (not only lemurs), improve habitat suitability and provide buffers and corridors between forest blocks (Waeber et al., Reference Waeber, Rafanoharana, Rasamuel, Wilmé, Bakar and Suratman2020; Ralimanana et al., Reference Ralimanana, Perrigo, Smith, Borrell, Faurby and Rajaonah2022).

Acknowledgements

We thank M. Fisher, P.P. Lowry II and a reviewer for their thoughtful comments on the manuscript. This research received no specific grant from any funding agency or commercial or not-for-profit sectors.

Author contributions

Conceptualization: POW, LW, JUG; methodology: SCR, FODA, HAR, LW; validation: LW, JUG; analysis: SCR, FODA, HAR, LW, JUG; data curation: SCR, FODA; writing: LW, JUG; supervision and project administration: LW.

Conflicts of interest

None.

Ethical standards

The research abided by the Oryx guidelines on ethical standards and was approved by the Ethical Standards Committee of the Institute of Animal Cell and Systems Biology (Universität Hamburg, Germany).

Data availability

No new data were created or analysed in this study. We reassessed publicly available data as described in the Methods section.

Footnotes

The supplementary material for this article is available at doi.org/10.1017/S0030605323001175

References

Andrianambinina, F.O.D., Waeber, P.O., Schuurman, D., Lowry, P.P. & Wilmé, L. (2022) Clarification on protected area management efforts in Madagascar during periods of heightened uncertainty and instability. Madagascar Conservation & Development, 17, 2528.CrossRefGoogle Scholar
Birkinshaw, C., Lowry II, P.P., Raharimampionona, J. & Aronson, J. (2013) Supporting Target 4 of the Global Strategy for Plant Conservation by integrating ecological restoration into the Missouri Botanical Garden's Conservation Program in Madagascar. Annals of the Missouri Botanical Garden, 99, 139146.CrossRefGoogle Scholar
Borgerson, C., Johnson, S.E., Hall, E., Brown, K.A., Narváez-Torres, P.R., Rasolofoniaina, B.J.R. et al. (2022) A national-level assessment of lemur hunting pressure in Madagascar. International Journal of Primatology, 43, 92113.CrossRefGoogle Scholar
Brown, J.H. (1995) Macroecology. University of Chicago Press, Chicago, USA.Google Scholar
Brown, J.H. & Lomolino, M.V. (1998) Biogeography, 2nd edition. Sinauer Associates, Sunderland, USA.Google Scholar
Brown, J.L. & Yoder, A.D. (2015) Shifting ranges and conservation challenges for lemurs in the face of climate change. Ecology and Evolution, 5, 11311142.CrossRefGoogle ScholarPubMed
Cowlishaw, G. (1999) Predicting the pattern of decline of African primate diversity: an extinction debt from historical deforestation. Conservation Biology, 13, 11831193.CrossRefGoogle Scholar
Donati, G., Ramanamanjato, J.-B., Blum, L.J., Flury, E. & Ganzhorn, J.U. (2021) New reforestation project in southern Madagascar to prevent the extinction of local endemic species. Oryx, 55, 654654.CrossRefGoogle Scholar
Eklund, J., Jones, J.P.G., Räsänen, M., Geldmann, J., Jokinen, A.-P., Pellegrini, A. et al. (2022) Elevated fires during COVID-19 lockdown and the vulnerability of protected areas. Nature Sustainability, 5, 603609.CrossRefGoogle Scholar
Estrada, A., Garber, P.A., Rylands, A.B., Roos, C., Fernandez-Duque, E., Di Fiore, A. et al. (2017) Impending extinction crisis of the world's primates: why primates matter. Science Advances, 3, e1600946.CrossRefGoogle ScholarPubMed
Fahrig, L. (2017) Ecological responses to habitat fragmentation per se. Annual Review of Ecology, Evolution, and Systematics, 48, 414.CrossRefGoogle Scholar
Ganzhorn, J.U. (1987) A possible role of plantations for primate conservation in Madagascar. American Journal of Primatology, 12, 205215.CrossRefGoogle ScholarPubMed
Ganzhorn, J.U., Goodman, S.M., Ramanamanjato, J.-B., Ralison, J., Rakotondravony, D. & Rakotosamimanana, B. (2000) Effects of fragmentation and assessing minimum viable populations of lemurs in Madagascar. Bonner Zoologische Monographien, 46, 265272.Google Scholar
Gardner, C.J., Nicoll, M.E., Birkinshaw, C., Harris, A., Lewis, R.E., Rakotomalala, D. & Ratsifandrihamanana, A.N. (2018) The rapid expansion of Madagascar's protected area system. Biological Conservation, 220, 2936.CrossRefGoogle Scholar
Gérard, A., Ganzhorn, J.U., Kull, C.A. & Carrière, S.M. (2015) Possible roles of introduced plants for native vertebrate conservation: the case of Madagascar. Restoration Ecology, 23, 768775.CrossRefGoogle Scholar
Goodman, S.M., Raherilalao, M.J. & Wohlhauser, S. (eds.) (2018) Les Aires Protégées Terrestres de Madagascar: Leur Histoire, Description et Biote. Association Vahatra, Antananarivo, Madagascar.Google Scholar
Goodman, S.M., Rakotondravony, D., Schatz, G. & Wilmé, L. (1996) Species richness of forest-dwelling birds, rodents and insectivores in a planted forest of native trees: a test case from Ankaratra, Madagascar. Ecotropica, 2, 109120.Google Scholar
Harcourt, A.H. (2002) Empirical estimates of minimum viable population sizes for primates: tens to tens of thousands. Animal Conservation, 5, 237244.CrossRefGoogle Scholar
Hending, D., Andrianiaina, A., Rakotomalala, Z. & Cotton, S. (2018) The use of vanilla plantations by lemurs: encouraging findings for both lemur conservation and sustainable agroforestry in the Sava region, northeast Madagascar. International Journal of Primatology, 39, 141153.CrossRefGoogle Scholar
Hending, D., Randrianarison, H., Andriamavosoloarisoa, N.N.M., Ranohatra-Hending, C., McGabe, G., Cotton, S. et al. (2022) A new population of mouse lemurs (Microcebus sp.) from north-western Madagascar, with population size and density estimates. Primate Conservation, 36, 103111.Google Scholar
Holloway, L. (2003) Ecosystem restoration and rehabilitation in Madagascar. In The Natural History of Madagascar (eds Goodman, S.M. & Benstead, J.), pp. 14441451. University of Chicago Press, Chicago, USA.Google Scholar
IUCN (2001) IUCN Red List Categories and Criteria: Version 3.1. IUCN Species Survival Commission, Gland, Switzerland, and Cambridge, UK.Google Scholar
Jenkins, R.K.B., Tognelli, M.F., Bowles, P., Cox, N., Brown, J.L., Chan, L. et al. (2014) Extinction risks and the conservation of Madagascar's reptiles. PLOS One, 9, e100173.CrossRefGoogle ScholarPubMed
Jolly, A., Dobson, A., Rasamimanana, H.M., Walker, J., O'Connor, S., Solberg, M. & Perel, V. (2002) Demography of Lemur catta at Berenty Reserve, Madagascar: effects of troop size, habitat and rainfall. International Journal of Primatology, 23, 327353.CrossRefGoogle Scholar
Kappeler, P.M., Markolf, M., Rasoloarison, R.M., Fichtel, C. & Durbin, J. (2022) Complex social and political factors threaten the world's smallest primate with extinction. Conservation Science and Practice, 4, e12776.CrossRefGoogle Scholar
Kling, K.J., Yaeger, K. & Wright, P.C. (2020) Trends in forest fragment research in Madagascar: documented responses by lemurs and other taxa. American Journal of Primatology, 82, e23092.CrossRefGoogle ScholarPubMed
Konersmann, C., Noromiarilanto, F., Ratovonamana, Y.R., Brinkmann, K., Jensen, K., Kobbe, S. et al. (2022) Using utilitarian plants for lemur conservation. International Journal of Primatology, 43, 10261045.CrossRefGoogle Scholar
Kremen, C., Cameron, A., Moilanen, A., Phillips, S.J., Thomas, C.D., Beentje, H. et al. (2008) Aligning conservation priorities across taxa in Madagascar with high-resolution planning tools. Science, 320, 222226.CrossRefGoogle ScholarPubMed
Kuussaari, M., Bommarco, R., Heikkinen, R. K., Helm, A., Krauss, J., Lindborg, R. et al. (2009) Extinction debt: a challenge for biodiversity conservation. Trends in Ecology & Evolution, 24, 564571.CrossRefGoogle ScholarPubMed
Laurance, W.F., Useche, D.C., Rendeiro, J., Kalka, M., Bradshaw, C.J.A., Sloan, S.P. et al. (2012) Averting biodiversity collapse in tropical forest protected areas. Nature, 489, 290–204.CrossRefGoogle ScholarPubMed
Lavialle, J., Carrière, S.M., Miandrimanana, C., Tilahimena, A., Birkinshaw, C.R. & Aronson, J. (2015) Complementarity of native and introduced tree species: exploring timber supply on the east coast of Madagascar. Madagascar Conservation & Development, 10, 137143.CrossRefGoogle Scholar
Louis, E.E., Bailey, C.A., Sefczek, T.M., Raharivololona, B., Schwitzer, C., Ratsimbazafy, J. et al. (2020) Lepilemur grewcockorum. In The IUCN Red List of Threatened Species 2020. dx.doi.org/10.2305/IUCN.UK.2020-2.RLTS.T136771A115585939.en.Google Scholar
Lowry II, P.P., Schatz, G.E. & Phillipson, P.B. (1997) The classification of natural and anthropogenic vegetation in Madagascar. In Natural Change and Human Impact in Madagascar (eds Goodman, S.M. & Patterson, B.D.), pp. 93123. Smithsonian Institution Press, Washington, DC, USA.Google Scholar
MacArthur, R.H. & Wilson, E.O. (1967) The Theory of Island Biogeography. Princeton University Press, Princeton, USA.Google Scholar
Manjaribe, C., Frasier, C.L., Rakouth, B. & Louis, E.E. Jr (2013) Ecological restoration and reforestation of fragmented forests in Kianjavato. International Journal of Ecology, 2013, 726275.CrossRefGoogle Scholar
Miller, J.S. & Morgan, H.A.P. (2011) Assessing the effectiveness of Madagascar's changing protected areas system: a case study of threatened Boraginales. Oryx, 45, 201209.CrossRefGoogle Scholar
Mittermeier, R.A., Louis, E.E. Jr, Richardson, M., Schwitzer, C., Langrand, O., Rylands, A.B. et al. (2010) Lemurs of Madagascar. Conservation International, Bogota, Columbia.Google Scholar
Montero, B.K., Refaly, E., Ramanamanjato, J.-B., Randriatafika, F., Rakotondranary, S.J., Wilhelm, K. et al. (2019) Challenges of next-generation sequencing in conservation management: insights from long-term monitoring of corridor effects on the genetic diversity of mouse lemurs in a fragmented landscape. Evolutionary Applications, 12, 425442.CrossRefGoogle Scholar
Morelli, T.L., Smith, A.B., Mancini, A.N., Balko, E.A., Borgerson, C., Dolch, R. et al. (2020) The fate of Madagascar's rainforest habitat. Nature Climate Change, 10, 8996.CrossRefGoogle Scholar
Moat, J. & Smith, P. (2007) Atlas of the Vegetation of Madagascar. Kew Publishing, Royal Botanic Gardens, Kew, UK.Google Scholar
Phillips, A.W. (2004) The history of the international system of protected area management categories. Parks, 14, 414.Google Scholar
Poelstra, W., Montero, B.K., Lüdemann, J., Yang, Z., Rakotondranary, S.J., Hohenlohe, P. et al. (2022) RADseq data reveal a lack of admixture in a mouse lemur contact zone contrary to previous microsatellite results. Proceedings of the Royal Society B, 289, 20220596.CrossRefGoogle Scholar
Rafanoharana, S.C., Andrianambinina, F.O.D., Rasamuel, H.A., Rakotoarijaona, M.A., Ganzhorn, J.U., Waeber, P.O. & Wilmé, L. (2021) Exemplifying stratified deforestation in four protected areas in Madagascar. Forests, 12, 1143.CrossRefGoogle Scholar
Rafanoharana, S.C., Andrianambinina, F.O.D., Rasamuel, H.A., Rakotoarijaona, M.A., Waeber, P.O., Ganzhorn, J.U. & Wilmé, L. (2023) Canopy density thresholds for improved forests cover estimation in protected areas of Madagascar. Environmental Research Communications, 5, 071003.CrossRefGoogle Scholar
Ralimanana, H., Perrigo, A.L., Smith, R.J., Borrell, J.S., Faurby, S., Rajaonah, M.T. et al. (2022) Madagascar's extraordinary biodiversity: threats and opportunities. Science, 378, eadf1466.CrossRefGoogle ScholarPubMed
Randriamady, H.J., Park, S., Andrianarimanana, D., Berobia, A. & Golden, C.D. (2021) The effect of conservation policies on wildlife hunting and consumption in north-eastern Madagascar. Environmental Conservation, 48, 225232.CrossRefGoogle Scholar
Reuter, K.E., Mittermeier, R.A. & Schwitzer, C. (2020) Microcebus boraha. In The IUCN Red List of Threatened Species 2020. dx.doi.org/10.2305/IUCN.UK.2020-3.RLTS.T163314140A182240168.en.Google Scholar
Schwitzer, C., Mittermeier, R.A., Johnson, S.E., Donati, G., Irwin, M., Peacock, H. et al. (2014) Averting lemur extinctions amid Madagascar's political crisis. Science, 343, 842843.CrossRefGoogle ScholarPubMed
Steffens, K.J.E. (2020) Lemur food plants as options for forest restoration in Madagascar. Restoration Ecology, 28, 15171527.CrossRefGoogle Scholar
Steffens, T.S., Ramsay, M.S., Malabet, F.M. & Lehman, S.M. (2022) The effects of forest loss and fragmentation on non-volant mammals in Madagascar. In The New Natural History of Madagascar, Volume 1 (ed. Goodman, S.M.), pp. 18121817. Princeton University Press, Princeton, USA.CrossRefGoogle Scholar
Stoudmann, N., Savilaakso, S., Waeber, P.O., Wilmé, L., Garcia, C., Byrne, J. & Adams, V.M. (2023) Overview of evidence on mechanisms affecting the outcomes of terrestrial multiple-use protected areas. One Earth, 6, 492-504.CrossRefGoogle Scholar
Strier, K.B. (2021) The limits of resilience. Primates, 62, 861868.CrossRefGoogle ScholarPubMed
Tagliari, M.M., Danthu, P., Leong Pock Tsy, J.M., Cornu, C., Lenoir, J., Carvalho-Rocha, V. et al. (2021) Not all species will migrate poleward as the climate warms: The case of the seven baobab species in Madagascar. Global Change Biology, 27, 6071-6085.CrossRefGoogle ScholarPubMed
Tattersall, I. & Cuozzo, F.P. (2018) Systematics of the extant Malagasy lemurs (order Primates). In Les Aires Protégées Terrestres de Madagascar: Leur Histoire, Description et Biote, Volume 1 (eds Goodman, S.M., Raherilalao, M.J. & Wohlauser, S.), pp. 403442. Association Vahatra, Antananarivo, Madagascar.Google Scholar
Vieilledent, G., Allnutt, T., Grinand, C., Pedrono, M., Rakotoarijaona, J.-R. & Razafimpahanana, D. (2021) BioSceneMada: Scénarios d’évolution de la biodiversité sous l'effet conjoint du changement climatique et de la déforestation à Madagascar. Rapport final. Centre for International Cooperation in Agronomic Research for Development, Paris, France. bioscenemada.cirad.fr/wp-content/uploads/2021/01/Restitution_FFEM_BioSceneMada.pdf [accessed 25 May 2023].Google Scholar
Vieilledent, G., Allnutt, T.F., Grinand, C., Pedrono, M., Razafimpahanana, A. & Rakotoarijaona, J.-R. (2020) Scénarios de la biodiversité sous l’effet conjoint du changement climatique et de la déforestation à Madagascar. CIRAD, Paris, France. bioscenemada.cirad.fr/wp-content/uploads/2021/01/Rapport_Final_BioSceneMada.pdf [accessed 9 October 2023].Google Scholar
Vieilledent, G., Cornu, C., Cuní Sanchez, A., Leong Pock-Tsy, J.M. & Danthu, P. (2013) Vulnerability of baobab species to climate change and effectiveness of the protected area network in Madagascar: towards new conservation priorities. Biological Conservation, 166, 1122.CrossRefGoogle Scholar
Vieilledent, G., Grinand, C., Rakotomalala, F.A., Ranaivosoa, R., Rakotoarijaona, J.R., Allnutt, T.F. et al. (2018) Combining global tree cover loss data with historical national forest cover maps to look at six decades of deforestation and forest fragmentation in Madagascar. Biological Conservation, 222, 189197.CrossRefGoogle Scholar
Waeber, P.O., Rafanoharana, S., Rasamuel, H.A. & Wilmé, L. (2020) Parks and reserves in Madagascar: managing biodiversity for a sustainable future. In Protected Areas, National Parks and Sustainable Future (eds Bakar, A.N. & Suratman, M.N.), pp. 89108. IntechOpen, London, UK.Google Scholar
Wilmé, L., Goodman, S.M. & Ganzhorn, J.U. (2006) Biogeographic evolution of Madagascar's microendemic biota. Science, 312, 10631065.CrossRefGoogle ScholarPubMed
Wilmé, L., RavokatraI, M., Dolch, R., Schuurman, D., Mathieu, E., Schuetz, H. et al. (2012) Toponyms for centers of endemism in Madagascar. Madagascar Conservation & Development, 7, 3040.CrossRefGoogle Scholar
Zinner, D., Wygoda, C., Razafimanantsoa, L., Rasoloarison, R., Andrianandrasana, H. & Ganzhorn, J.U. (2014) Analysis of deforestation patterns in the Central Menabe, Madagascar, between 1973 and 2010. Regional Environmental Change, 14, 157166.CrossRefGoogle Scholar
Figure 0

Table 1 The protected area categories system advocated by IUCN since 1994 (Phillips, 2004).

Figure 1

Fig. 1 Size distribution of protected areas in Madagascar (a) as a whole and (b) as forest blocks in 2017 and projected to 2050 based on current deforestation rates (Table 2). Size classes double from one class to the next. Values on the x-axes are the midpoints in each category (e.g. 5 km2 represents blocks of 0–9.99 km2, 15 km2 represents blocks of 10–19.99 km2, etc.).

Figure 2

Table 2 Number and size of forest blocks and total forest area in 2017, and deforestation per year during 2015–2017 in the protected areas of Madagascar (Fig. 1), by IUCN category, and projections of per cent forest loss during 2017–2050 and total forest area in 2050.

Figure 3

Fig. 2 Occurrence of lemur species in the protected areas of Madagascar as of 2017. The numbers on the x-axis represent the number of protected areas where any given lemur species has been recorded (e.g. 30 species are known from a single protected area and 10 species from two areas).

Figure 4

Fig. 3 Lemur subpopulations occurring in different-sized forest blocks in Madagascar in 2017 and 2050, assuming the same deforestation rates as recorded during 2015–2017. Size classes double from one class to the next. Values on the x-axis are the midpoints in each category (e.g. 5 km2 represents blocks of 0–9.99 km2, 15 km2 represents blocks of 10–19.99 km2, etc.).

Figure 5

Fig. 4 (a) Forest cover in Madagascar in 2017, (b) projection of deforestation (from Vieilledent et al., 2021) assuming a constant deforestation rate of 100,000 ha/year (corresponding to 1.2% on the basis of the forest cover of 2010) from 2010 to 2050, and (c) the locations of protected areas, by IUCN category (Table 1). NA, not assigned to an IUCN category. (Readers of the printed journal are referred to the online article for a colour version of this figure.)

Supplementary material: File

Rafanoharana et al. supplementary material

Rafanoharana et al. supplementary material
Download Rafanoharana et al. supplementary material(File)
File 92 KB