Policy Research Working Paper 11076 Bridging Conflicts and Biodiversity Protection The Critical Role of Reliable and Comparable Data Brian Blankespoor Susmita Dasgupta David Wheeler Development Research Group Development Data Group & Environment Global Department February 2025 Policy Research Working Paper 11076 Abstract Biodiversity is essential for ecological stability, human providing baseline data to guide conservation strategies. well-being, and economic progress, providing critical Using newly developed World Bank species occurrence ecosystem services such as clean water, food, and climate maps based on open-access, date-stamped records from regulation. However, it faces unprecedented threats, with the Global Biodiversity Information Facility, the study extinction rates accelerating to 1,000 times the natural base- evaluates species richness, endemism, and extinction risks line due to habitat destruction, overexploitation, pollution, across 35 non-determined legal status territories, 19 con- invasive species, illegal trade, and climate change. Effective flict-affected countries, 20 fragile states, 18 marine joint conservation requires urgent, coordinated global action, as regimes, and 311 international river basins. The data sets ecosystems and species habitats often transcend national reveal that these regions host numerous, often vulnerable, borders. Collaboration among governments, industries, and species. Biodiversity conservation emerges as a pathway communities is essential to restore habitats, protect endan- for trust-building and collaboration, aligning stakeholders gered species, strengthen policies, and enforce conservation around shared goals such as climate resilience and sustain- measures. The challenges of biodiversity conservation are able livelihoods. Reliable and comparable data sets are particularly acute in geopolitically sensitive and overlapping critical for evidence-based planning, fostering dialogue regions, including non-determined legal status territories, and cooperation among divided groups. The estimates fragile and conflict-affected situations, and transboundary presented in this paper aim to support robust, data-driven ecosystems. In these areas, effective conservation is hindered strategies to safeguard biodiversity in geopolitically sensitive by weak policies, inconsistent enforcement, and institu- and overlapping regions, with far-reaching implications for tional fragility. This paper addresses these challenges by global conservation and international cooperation. This paper is a product of the Development Research Group and the Development Data Group, Development Economics and the Environment Global Department. It is part of a larger effort by the World Bank to provide open access to its research and make a contribution to development policy discussions around the world. Policy Research Working Papers are also posted on the Web at http://www.worldbank.org/prwp. The authors may be contacted at bblankespoor@worldbank.org. The Policy Research Working Paper Series disseminates the findings of work in progress to encourage the exchange of ideas about development issues. An objective of the series is to get the findings out quickly, even if the presentations are less than fully polished. The papers carry the names of the authors and should be cited accordingly. The findings, interpretations, and conclusions expressed in this paper are entirely those of the authors. They do not necessarily represent the views of the International Bank for Reconstruction and Development/World Bank and its affiliated organizations, or those of the Executive Directors of the World Bank or the governments they represent. Produced by the Research Support Team Bridging Conflicts and Biodiversity Protection: The Critical Role of Reliable and Comparable Data Brian Blankespoor,a Susmita Dasgupta,b and David Wheelerc a. Senior Geographer, Development Economics Data Group, World Bank, bblankespoor@worldbank.org b. Lead Environmental Economist, Development Research Group, World Bank, sdasgupta@worldbank.org c. Consultant, World Bank, wheelrdr@gmail.com Corresponding author: Brian Blankespoor, Senior Geographer, Development Economics Data Group, MC- 9-204, The World Bank, 1818 H Street, Washington, DC 20008, USA. Tel: 1-202-473-1546. Email: bblankespoor@worldbank.org Keywords: Biodiversity Conservation; Non-determined legal status Territories; Fragile and Conflict-Affected Situations, Transboundary Ecosystems; Marine Joint Regimes; International River Basins JEL Classifications: Q34; Q25; Q57 Funding: This research was funded by the Global Environment Facility (GEF). Acknowledgments: This research was funded by a grant from the Global Environment Facility to a World Bank program managed by Nagaraja Harshadeep Rao, Susmita Dasgupta and Brian Blankespoor. Georeferenced species occurrences reported by GBIF were accessed from Google BigQuery on 2024-02- 17. We are thankful to Ms. Polly Means and Mr. Pritthijit (Raja) Kundu for their help with the graphics. The findings, interpretations, and conclusions expressed in this paper are entirely those of the authors. They do not necessarily represent the views of the International Bank for Reconstruction and Development/World Bank and its affiliated organizations, or those of the Executive Directors of the World Bank or the governments they represent. Introduction Biodiversity conservation is essential for sustainable development, poverty reduction, and a healthy planet. It supports ecosystems that are fundamental to human livelihoods by providing food, clean water, and climate stability. Healthy ecosystems ensure the availability of natural resources critical to agriculture, fishing, and forestry, helping to alleviate poverty and promote sustainable economic growth. Additionally, biodiversity preservation supports industries like ecotourism and pharmaceuticals, which generate revenue and create jobs, further contributing to shared prosperity. Maintaining biodiversity is also a key to a livable planet, as it strengthens the resilience of ecosystems that regulate the climate by sequestering carbon and mitigating the impacts of climate change. Ecosystems such as forests, wetlands, and oceans act as natural buffers, stabilizing global temperatures and sustaining life on Earth. Thus, investing in biodiversity conservation is crucial not only for environmental health, but also for human well-being and global sustainability. However, biodiversity is declining at an alarming rate. A recent UN report by the Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services revealed that 1 million species are near extinction, with the rate of extinctions accelerating despite increasing awareness of the interconnectedness between human life and nature (IPBES 2019). This report, based on a systematic review of approximately 15,000 scientific and governmental sources, aligns with the findings of the Living Planet Index, 1 which has recorded a 68% decline in global biodiversity since 1970. The primary drivers of this crisis include habitat destruction, overexploitation of resources, pollution, illegal wildlife trade, invasive species and climate change. In response to these unprecedented losses, immediate and coordinated international action is required. Every country and territory must actively engage in biodiversity conservation to halt further biodiversity decline. Nations need to implement effective policies and conservation strategies tailored to local ecosystems, while leveraging global frameworks such as the Convention on Biological Diversity (CBD) and the United Nations Sustainable Development Goals (SDGs). One of the significant barriers to effective conservation is the impact of human conflicts, particularly in weakly-governed areas. These regions often experience destructive effects on biodiversity, spanning terrestrial, marine, and freshwater ecosystems. Physical damage to landscapes, habitat destruction, pollution, and overexploitation of natural resources are common consequences of such conflicts. Military dimensions of conflicts can further exacerbate these challenges by diverting resources from environmental protection and disrupting natural food webs and migratory patterns (Rist, Norstrom, and Queiroz 2024; Parkinson and Cottrell 2022). The academic literature extensively documents the challenges of biodiversity conservation within 1 https://www.livingplanetindex.org/ 2 non-determined legal status territories and conflict zones (e.g., Greiner 2012; Daskin and Pringle 2018; Hanson 2018). Moreover, weak governance and fragmented authority in non-determined legal status territories create additional complications. Conflicting territorial claims can undermine environmental protection and allow unchecked exploitation of natural resources. The institutional landscape in these areas often features competing authorities, which results in inconsistencies in law enforcement and resource management (Beckman, 2013). Although international interventions aim to foster stability, they frequently lack robust enforcement mechanisms. This instability can prolong conflicts, deepen socio-economic inequalities, and intensify environmental degradation (Buhaug et al., 2014). In conflict zones, governance often collapses, making effective environmental protection nearly impossible. For instance, recent events in the Syrian Arab Republic and the Republic of Yemen have led to the collapse of public institutions, with attention shifting to immediate survival and security needs, leaving environmental concerns neglected (World Bank, 2011). To address these challenges, efforts to conserve biodiversity in affected regions must be preceded by the restoration of national and international cooperation to rebuild trust and establish shared conservation goals (Gaind et al., 2016). While human conflict areas present significant challenges for biodiversity conservation due to governance gaps and instability, transboundary river basins also face complex issues—ranging from competing national interests to opportunities for cooperation—requiring coordinated efforts to address shared environmental concerns and manage resources sustainably across borders. Effective conservation in such areas requires objective, reliable, and comparable data from all riparian entities. In practice, weak governance and political or social instability often make it difficult for officially-designated institutions to collect the necessary data (Cohen and Arieli 2011). This is particularly true in regions with competing territorial claims, where data collection and conservation efforts are frequently obstructed. In this context, recent studies (Turner et al., 2015; Levin et al., 2019; Mobaied and Rudant 2019; Garzón and Valánszki 2020; Aung 2021) have emphasized the potential importance of remote sensing from satellite platforms. These technologies offer a promising solution by providing valuable and consistently collected real-time data from areas that may otherwise be inaccessible or where traditional monitoring is too challenging. The Global Biodiversity Information Facility (GBIF) is also playing a critical role in overcoming these barriers. By acquiring and distributing data on species sightings from concerned organizations and individuals, the GBIF is providing essential information in areas where officially- supported monitoring may be sparse or difficult to implement. This collaboration strengthens global conservation efforts by making vital data more accessible, even in fragile or conflict- affected regions. To implement effective conservation strategies in such contexts, accurate, location-specific data are crucial. The importance of this data for identifying critical biodiversity areas and tracking 3 conservation progress has been highlighted in numerous studies. However, inconsistencies in data across countries and administrative boundaries hinder the accurate assessment of ecosystem health and biodiversity trends (Urbano et al., 2024; Geijzendorffer et al., 2016; Pereira et al., 2013). Moreover, the growing gap between emerging threats and infrequently updated data, often managed by underfunded institutions, presents an ongoing challenge. To help address this gap, we have produced new public datasets by utilizing millions of georeferenced species occurrence records from the Global Biodiversity Information Facility (GBIF) (Dasgupta et al. 2024a). Using machine-based pattern recognition, we developed a comprehensive database covering the occurrence regions of nearly 600,000 species. These maps were validated by comparing them with expert-reported maps for mammals, ants, and vascular plants, revealing strong correlations in global distribution patterns. Our expanded database includes a broad array of species across terrestrial, freshwater, and marine environments, encompassing arthropods, mollusks, invertebrates, plants, fungi, and more, alongside traditionally studied amphibians, birds, fish, reptiles, and mammals. Figure 1 illustrates the composition of this expanded database, revealing new global distribution patterns that can inform conservation planning. In this paper, we focus on the implications of our results for biodiversity protection in transboundary regions,2 joint marine regions, 3 non-determined legal status areas, 4 and fragile and conflict-affected situations areas (FCS). 5 Conflicts and coordination failures in such areas have numerous direct and indirect impacts on biodiversity (see Rist, Norstrom and Queiroz (2024) for a review of the relationships between biodiversity, peace and conflict). These are often difficult to address in non-determined legal status areas and FCSs because of weak governance, limited administrative capacity, and insufficient institutions and policies. The effective protection of biodiversity in transboundary areas must rely on cooperation among the parties involved. 2 A transboundary area is an area of land and/or sea that straddles one or more boundaries between states, sub-national units such as provinces and regions, autonomous areas, and/or areas beyond the limits of national sovereignty or jurisdiction. 3 A joint marine regime governs shared Exclusive Economic Zones (EEZs) https://www.marineregions.org/eezlinetype.php#:~:text=Joint%20regime,exploitation%20of%20natural%20marine %20resources. 4 A non-determined legal status area is an area claimed by two or more countries without a determined legal status. Disputed areas can arise from a variety of factors, including the historical background, different religious or ethnic perspectives, possession of strategic natural resources, and fundamental changes in domestic and international environments. 5 The World Bank has recently released a list of Fragile and Conflict-Affected Situations. The conflict- affected countries are Afghanistan, Burkina Faso, Cameroon, the Central African Republic, the Democratic Republic of Congo, Ethiopia, Haiti, Iraq, Lebanon, Mali, Mozambique, Myanmar, Niger, Nigeria, Somalia, South Sudan, Sudan, Syria, Ukraine, the West Bank and Gaza (territory), and Yemen. Additionally, countries facing institutional and social fragility include Burundi, Chad, the Comoros, the Republic of Congo, Eritrea, Guinea-Bissau, Kiribati, Kosovo, Libya, the Marshall Islands, the Federated States of Micronesia, Papua New Guinea, São Tomé and Príncipe, the Solomon Islands, Timor-Leste, Tuvalu, the República Bolivariana de Venezuela, and Zimbabwe. 4 Preserving habitats for endemic species, those with restricted ranges, and species at high extinction risk requires special conservation measures tailored to vulnerable and geopolitically complex regions. The expansion of species information using GBIF records offers a significant expansion of the objective, comparable and reliable data that are critical for successful implementation of transboundary and fragile/conflict state conservation measures. In this paper, we illustrate the potential contribution of our GBIF database data with results for 38 non-determined legal status area areas, 19 conflict-affected countries, 19 countries with pronounced institutional and social fragility, and 311 international river basins. 5 Figure 1: Total count of species Species [Class/Order] Group Count Amphibians 5,026 Vertebrates Birds 10,845 [Class] Mammals 4,377 50,825 Reptiles 7,544 Fish 23,033 Araneae 10,307 Coleoptera 43,660 Arthropods Diptera 23,321 [Order] Hemiptera 13,123 209,908 Hymenoptera 25,924 Lepidoptera 50,037 Other 43,536 Asparagales 17091 Asterales 22841 Caryophyllales 9321 Ericales 8545 Vascular Plants Fabales 16194 [Order] Gentianales 13317 229,595 Lamiales 16436 Malpighiales 12632 Myrtales 10253 Poales 16,433 Other 86,532 Fungi 37,450 Non-animal, non-plant species: protozoans, bacteria, etc. 16,540 Other Animals: Molluscs, etc. 53,214 Total 597,532 6 Data and Method The data for this study have been provided by the Global Biodiversity Information Facility (GBIF), a global network, funded by various national governments, that offers open access to comprehensive data on global biodiversity. The GBIF provides a repository of georeferenced, time-stamped species occurrence records that are constantly updated in collaboration with the Catalogue of Life partnership (https://www.catalogueoflife.org), Biodiversity Information Standards (https://www.tdwg.org/), Consortium for the Barcode of Life (CBOL) (http://www.barcodeoflife.org/), Encyclopedia of Life (EOL) (http://eol.org), Global Earth Observation System of Systems (GEOSS) (https://earthobservations.org/geoss.php) and other organizations. The GBIF records span multiple taxa, including animals, plants, fungi, and microbes. Users can directly access these records through GBIF's Occurrence and Maps APIs (https://www.gbif.org/developer/occurrence, https://www.gbif.org/developer/maps), and access to the database is also provided by cloud platforms like Google BigQuery and Amazon Web Services (AWS). For the analysis presented here, we processed large-scale datasets using Google BigQuery, which efficiently handles vast amounts of biodiversity data. The GBIF occurrence records were filtered to include only those that met specific criteria: we selected records from 1970 onwards and focused on species that had at least three unique reporting locations and five occurrence reports. Additionally, to manage computational efficiency, we limited species with excessive data, such as the American Robin (Turdus migratorius), to a maximum of 20,000 randomly sampled records. This filtering approach ensured that computational resources were effectively used, without sacrificing the integrity of the data. We adhered to GBIF’s occurrence reporting protocols, which ensure consistency in the way species records are documented and shared across the global community. This adherence to protocol is essential for maintaining the reliability and comparability of biodiversity data. Species Occurrence Mapping To generate species occurrence maps, we employed machine-based techniques for pattern recognition and cluster analysis. For most species (93.6% of the dataset), we applied a spatial boundary construction method known as the alphahull algorithm (Pateiro-López and Rodríguez- Casal, 2010). This method, well-established in the literature (Guo et al., 2022; Kass et al., 2022), allowed for the precise delineation of species' occurrence regions across terrestrial, freshwater, coastal, and marine environments. For the remaining species, we utilized a k-means clustering algorithm combined with convex hulls to estimate their geographic distributions. To validate the accuracy of our generated maps, we compared them with expert-verified maps from well-regarded datasets of mammals (Marsh et al., 2022), ants (Kass et al., 2022), and vascular plants (Borgelt et al., 2022). These comparisons demonstrated strong correlations between our maps and those generated by subject-matter experts. Figure 2 provides two examples of species occurrence regions: one for an endemic species, Scherya bahiensis, which is 7 confined to a small region in Brazil, and one for a non-endemic species, Lagidium viscacia (the Mountain Viscacha), which has a broader distribution across several countries in South America. These examples illustrate the contrasting distribution patterns of species with restricted versus extensive geographic ranges. To illustrate, effective biodiversity conservation plans depend on accurately identifying regions with species that are either endemic (i.e., species confined to a specific geographic area, often within a single country) or facing high extinction risks. Extinction risk refers to the likelihood that a species will become extinct within a certain time frame and is quantified using various models. In this study, we estimate extinction risk using an ordered-logit model, a statistical technique that predicts categorical outcomes based on multiple variables. For this analysis, a high extinction risk is defined as a score above 80 out of 100, indicating a species with a significant threat of extinction. Utilizing our newly developed occurrence maps, we identified 267,522 endemic species (44.7% of the total species in our dataset) and 84,627 species whose small occurrence areas (defined as areas smaller than 25 km²) make them highly vulnerable to extinction. Occurrence area refers to the observed geographic range of a species, with smaller ranges often correlating with higher extinction risk due to habitat loss, climate change, or other threats. In addition, hundreds of thousands of species in our Global Biodiversity Information Facility (GBIF) database have not previously been assessed for extinction risks. To address this gap, we have incorporated location-specific threats (e.g., habitat destruction, pollution, or invasive species) and protection measures (e.g., conservation efforts or legal protections) into the extinction risk estimates for nearly 600,000 species. This includes 510,090 species that have not yet been evaluated for risk by the International Union for Conservation of Nature (IUCN) (Dasgupta et al. 2024b). 6 Geographic Boundaries for Conservation Analysis In addition to generating species occurrence maps, we overlaid various geographic boundaries to examine the influence of governance and territorial issues on biodiversity conservation. These boundaries included areas such as non-determined legal status areas, Fragile and Conflict- Affected Situations (FCSs), joint regimes of Exclusive Economic Zones (EEZs), and transboundary river basins, all of which present unique challenges for effective conservation. The boundaries for non-determined legal status areas and fragile/conflict states (FCSs) were obtained from the World Bank. The boundaries of joint EEZ regimes were sourced from the Flanders Marine Institute (2019), and the transboundary river basin boundaries were taken from McCracken and Wolf (2019), version 2022-03-07. The inclusion of non-determined legal status territories is critical because these regions often face unclear or disputed governance, which can hinder effective conservation efforts. These 6 Global Biodiversity Species Extinction Risks Data 8 areas may lack the institutional frameworks necessary for coordinated conservation activities, leading to unchecked exploitation of natural resources and increased threats to biodiversity. In some cases, these regions may be rich in biodiversity, but their legal ambiguity complicates the establishment of conservation policies and enforcement mechanisms. Fragile and Conflict-Affected Situations (FCSs) are also included due to the significant impact that political instability, civil unrest, and war can have on environmental protection. Biodiversity conservation in FCSs is particularly challenging, as the breakdown of governance structures often leads to deforestation, poaching, illegal mining, and other forms of environmental degradation. Moreover, these regions frequently lack the resources to prioritize environmental protection amid immediate humanitarian and security concerns, further exacerbating threats to biodiversity. Additional elements for our analysis are provided by terrestrial and marine water bodies that cross national boundaries. Their ecosystems are critical for biodiversity, but are often excluded from shared arrangements for water resource management. Even in cases where ecosystems are included, their protection depends upon monitoring and enforcement provisions that require sustained support. Our terrestrial analysis focuses on transboundary river basins, which are particularly vulnerable to unsustainable water management practices, pollution, and habitat loss. Managing transboundary river basins requires international cooperation to ensure the long-term health of their ecosystems. Conflicting national interests, such as competing demands for water, can complicate conservation efforts, making these regions particularly important to study. Our marine analysis focuses on transboundary overlaps in Exclusive Economic Zones (EEZs), which are formally managed by marine joint regimes with specific arrangements for the exploration and exploitation of natural marine resources (Flanders Marine Institute, 2019 and sourced from the United Nations' DOALOS repository). Like transboundary river basin arrangements, these regimes can be inconsistent in their attention to biodiversity management, particularly for migratory marine species. Cooperative governance in these joint regime areas is critical for ensuring that marine resources are used sustainably while safeguarding the biodiversity that exists in shared marine ecosystems. By overlaying these critical geopolitical boundaries onto our species occurrence maps, we aim to identify areas where conservation efforts may be more difficult due to political, legal, or social challenges. These areas are often at the intersection of biodiversity hotspots and governance weaknesses, making them crucial for targeted conservation actions and policy interventions. 9 Figure 2: Selected species occurrence regions Results Table 1: Area, human population count (WorldPop) and total species in geopolitically sensitive and overlapping areas Area (million square Human Population Total species 7 Kilometers) (millions) (thousands) Non-determined legal 4.6 2.1 55.8 status Territories Fragile and Conflict- 37.2 936 123.6 Affected Situations Marine Joint Regimes 0.4 0 61.8 Transboundary River 62 3,500 369.2 Basins 7 Total species is the number of unique species in each geographic category. Some species occur in more than one category. 10 Taken together, non-determined legal status territories, areas with fragile and conflict-affected situations status, joint marine regimes, and transboundary river basins cover significant portions of the world's terrestrial and marine areas. Non-determined legal status territories cover approximately 4.6 million square kilometers, while areas with fragile and conflict-affected status extend over 37 million square kilometers. Figure 3 shows the geographic distribution of FCS countries across the world. International joint marine regimes cover over 400,000 square kilometers, and transboundary river basins encompass a vast area of nearly 62 million square kilometers. These regions, often characterized by geopolitical tensions and environmental challenges, have substantial importance for international cooperation and conflict resolution. According to population data from WorldPop (Tatem 2017; WorldPop and CIESIN 2018), an estimated 2.1 million people reside within non-determined legal status territories, while around 936 million people live in areas marked by fragile and conflict situations. Furthermore, over 3.5 billion people inhabit regions dependent on shared water resources in transboundary river basins, underlining the complex interplay between population distribution and resource management in these geopolitically sensitive and overlapping areas. Figure 4 illustrates the log human population density in transboundary river basins across the world. The Role of Human Population Density Understanding the relationship between biodiversity and human population density is crucial for addressing the ongoing biodiversity crisis. As human populations grow and expand, the pressure on ecosystems intensifies, making it essential to explore how population density impacts biodiversity conservation. Human activities, particularly in densely populated areas, have been a major driver of ecosystem alteration, from habitat loss and fragmentation to overexploitation of resources. The clearing of forests and wetlands for agriculture, urban development, and infrastructure projects has directly contributed to the decline in species diversity and the disruption of critical ecological processes. Human population density often correlates with higher levels of resource consumption, which in turn often leads to greater environmental degradation. For example, densely populated urban areas tend to have higher pollution levels, increased waste production, and more extensive land conversion. These factors not only stress the natural environment, but also create challenges for species survival. As human settlements encroach on natural habitats, conflicts between humans and wildlife frequently emerge, exacerbating threats to biodiversity. Farmers may face crop damage from wildlife, leading to retaliatory killings, while wildlife may lose their habitats or be forced to migrate into more dangerous or fragmented areas. These interactions highlight the urgent need to assess how human population density contributes to habitat loss and species endangerment. At the same time, understanding population density's effects on biodiversity can inform strategies for fostering human-wildlife coexistence. Regions with higher population densities require innovative solutions, such as effective land-use planning, the establishment of wildlife corridors, 11 and community-based conservation initiatives. These approaches can help mitigate the impact of human activities on ecosystems, support sustainable agricultural practices, and reduce conflict. Engaging local communities in conservation efforts—particularly in high-density areas—can enhance stewardship, promote sustainable land-use practices, and encourage the protection of critical habitats. Ultimately, understanding the dynamics between human population density and biodiversity is essential for developing targeted strategies that address the complex interactions between people and nature. By evaluating the impacts of human settlements on ecosystems and promoting sustainable coexistence, we can create a more balanced approach to development and conservation that benefits both biodiversity and human well-being. Figure 3: Countries determined as Fragile and Conflict-affected Situations areas (FCS) in 2024 12 Figure 4: Log human population density in transboundary river basins Figure 5: Total count of critical species in geopolitically sensitive and overlapping areas As an aid to interpreting our results, the Venn diagram in Figure 5 provides an accounting for species in our database that are particularly critical for biodiversity analysis because they are endemic, have small habitats, or have extinction threat indicator values that exceed 80%. The figure shows that while many species are uniquely assigned to one of the three categories, others are in two or three. Among the nearly 600,000 species in our GBIF database, 51,779 have unique endemic assignment, 14,585 have unique small occurrence region assignment, and 6,090 have 13 unique high extinction threat assignment. Among species with non-unique assignments, 17,555 are endemic with small occurrence regions; 3,389 have small occurrence regions and extinction threat indicators higher than 80%; 4,118 are endemics with extinction threat indicators greater than 80%, and 9,230 are in all three categories. 8 As Table 2 and Figure 5 show, species in all three categories are amply represented in transboundary areas and Fragile and Conflict-Affected Situations. Overall, Table 2 shows that the number of species with potential concern is greatest in transboundary river basins (369,211), followed by fragile/conflict states (123,646), marine joint regimes (58,792) and non-determined legal status territories (55,641). Table 2 also shows that representation is very different by category. Species with small occurrence regions present the biggest challenge in non- determined legal status territories, fragile/conflict states and marine joint regimes, while endemic species dominate in transboundary river basins. Table 2: Species richness and count of critical species by geopolitically sensitive and overlapping areas Count of Species with Count of Species Count of Count of Small with Threats of Total Species Endemic Occurrence Extinction more (Presence) Species Region than 80% Non-determined legal status 55,641 123 3,238 854 Territories Fragile and Conflict - 123,646 8,649 10,793 3,958 Affected Situations Marine Joint 58,792 0 2,684 733 Regimes Transboundary 369,211 78,800 40,951 21,362 River Basins Figure 6 provides a summary perspective on the information in Figure 5 and Table 2. In the figure, the interior circles are labeled with the estimated total numbers of species in geopolitically sensitive and overlapping areas that are endemic, have small habitats, or have extinction probability indicators above 80%. The oblong extensions for each category are labeled with estimated total species in these categories that are not in geopolitically sensitive and overlapping 8 We should note that the data in Figure 1 are global in scope. Our discussion of these species in the context of transboundary areas and fragile/conflict states should not be taken to imply that they only inhabit those areas. 14 areas. As the figure clearly shows, geopolitically sensitive and overlapping areas also have high critical species intensity when compared with other global areas. Figure 6: Critical species in geopolitically sensitive and overlapping areas (GOSA) and other areas (Other) Figure 7 introduces another important dimension by showing that within each of the geopolitically sensitive and overlapping areas, representation of different taxa can vary widely. Particularly striking are variations in the representation of plants (green) and arthropods (gray) relative to representation for terrestrial vertebrates (brown) and fish (light blue). As we previously noted, our GBIF mapping exercise has greatly expanded geographic representation for plants and arthropods. In the current context, variations in this representation can provide important new information for the policy dialogue. Figure 8 provides a global perspective by displaying the same charts for all species in the database. Comparison with Figure 7 shows a close resemblance to the distributions for Transboundary River Basins, with somewhat greater representation for molluscs and other animals in the full global distribution. 15 Figure 7: Taxon variations (species class/order) in GSOA Non-determined Legal Status Areas Terrestrial Vertebrates Total Number of Species with Fish Extinction Threat exceeding Arthropods 80% Mollusca Other Animals Total Number of Endemic Vascular Plants Species Fungi with Small Occurrence Region Other non-animal non-plant species Total Number of Small Occurrence Region (50km x 50 km) Species Total Number of Endemic Species Total number 0 500 1000 1500 2000 2500 3000 3500 of species: 55,641 Fragile Conflict States Terrestrial Vertebrates Fish Arthropods Total Number of Species with Mollusca Extinction Threat exceeding 80% Other Animals Vascular Plants Total Number of Endemic Species Fungi with Small Occurrence Region Other non-animal non-plant species Total Number of Small Occurrence Region (50km x 50 km) Species Total Number of Endemic Species Total number 0 2,000 4,000 6,000 8,000 10,000 12,000 of species: 123,646 16 Marine Joint Regime Fish Arthropods Mollusca Total Number of Species with Other Animals Extinction Threat exceeding 80% Vascular Plants Fungi Total Number of Endemic Species Other non-animal non-plant species with Small Occurrence Region Total Number of Small Occurrence Region (50km x 50 km) Species Total Number of Endemic Species Total number of species: 58,792 0 500 1,000 1,500 2,000 2,500 3,000 Transboundary River Basins Terrestrial Vertebrates Total Number of Species Fish with Extinction Threat Arthropods exceeding 80% Mollusca Other Animals Total Number of Endemic Vascular Plants Species with Small Fungi Occurrence Region Other non-animal non-plant species Total Number of Small Occurrence Region (50km x 50 km) Species Total Number of Endemic Species Total number 0 20,000 40,000 60,000 80,000 of species: 369,211 17 Figure 8: Global taxon variations Table 3 summarizes the protection status of species in transboundary regions in analyses for international treaties and river basin organizations (RBOs). For species in critical categories (endemic, small range or high extinction threat indicator (ETI), between 4.9% and 9.6% are in basins that are not covered by international treaties, and between 12.8% and 29.9% are in basins not managed by RBOs. Between 4.9% and 9.4% are in basins not covered by treaties or RBOs. This lack of governance coverage is especially troubling for endemic species with small occurrence regions (9.4% without treaties; 29.9% without RBOs; 9.3% with neither) and high ETIs (9.6% without treaties, 29.6% without RBOs; 9.4% with neither). The absence of governance structures in these regions means that conservation efforts are more difficult to coordinate, and species are at heightened risk from habitat destruction, overexploitation, and other environmental threats. The findings in Table 3 highlight two major challenges for cooperation in transboundary river basins. First, even in areas where treaties or RBOs do exist, it is not guaranteed that species protection is a priority within these agreements. Many existing treaties and RBOs focus on issues such as water allocation and infrastructure development, but they may not explicitly address biodiversity conservation or the protection of species. This underscores the need for more targeted agreements within these frameworks that prioritize the protection of species, particularly those with small or restricted ranges that are highly vulnerable to environmental changes. Second, in areas where no treaties or RBOs are in place, the absence of formal governance makes it more difficult to establish and enforce conservation measures. In these regions, there is a 18 pressing need for alternative mechanisms to ensure that conservation stewardship responsibilities are both delegated and effectively monitored. This may involve the creation of ad hoc agreements between neighboring countries or the establishment of transboundary conservation initiatives that focus specifically on biodiversity protection. These initiatives could help fill the gaps where formal governance structures are lacking, promoting a more coordinated approach to conservation across national borders. Ultimately, the results from Table 3 underscore the urgent need for international cooperation to ensure the protection of species in transboundary river basins. Without adequate governance frameworks, both at the treaty and RBO level, the survival of many species in these regions remains uncertain. Efforts to strengthen governance, prioritize species protection within existing agreements, and develop new mechanisms for regions without formal frameworks are critical for the long-term success of biodiversity conservation in these ecologically important areas. Table 3: Transboundary river basins: species covered by treaties and river basin organizations % % % Without Total Without Without RBO or Species Treaty RBO Treaty Species Presence 369,211 4.93 12.78 4.87 Endemic 78,800 7.01 21.99 6.97 Small Occurrence Region 40,951 8.16 23.91 8.01 Extinction Threat Indicator (ETI) > 80 21,362 8.08 23.76 7.93 Endemic with Small Occurrence Region 24,288 9.38 29.85 9.28 Small Occurrence Region with ETI > 80 11,513 9.28 26.88 9.04 Endemic with ETI > 80 12,326 8.84 28.20 8.75 Endemic, Small Occurrence Region with ETI>80 8,339 9.57 29.57 9.44 Discussion The data provided by the Global Biodiversity Information Facility (GBIF) can play a pivotal role in identifying and protecting vulnerable species, especially those located in fragile regions and ecosystems that span multiple political jurisdictions. One of the primary benefits of GBIF-type 19 data is its ability to provide reliable and comparable information across borders, which is critical for the effective management of transboundary ecosystems and biodiversity. 9 For example, the Mekong River Basin, shared by six countries, relies on shared data to manage fisheries, water resources, and biodiversity effectively (Anh 2021; McPherson and Ropicki 2021). Similarly, the Central Albertine Rift, home to endangered species such as mountain gorillas, requires harmonized biodiversity data from Uganda, Rwanda, and the Democratic Republic of Congo to ensure conservation success (Plumptre, et al. 2010; Plumptre, et al. 2007). Variations in data collection methods, inconsistent monitoring standards, or the absence of cross-border data sharing can hinder ecosystem-level management efforts. The literature also emphasizes that standardized data collection improves the ability to track species trends, measure ecosystem health, and implement conservation strategies that address ecosystem-wide threats. Comparable data are also necessary for designing and implementing programs such as Transboundary Protected Areas. The estimates presented in this paper can help in setting up baselines for identifying priority areas for cooperative environmental protection. In another potential domain for GBIF contributions, international and regional treaties play a critical role in conserving natural resources and biodiversity, particularly in transboundary river basins, international waters, and joint marine areas. These treaties establish a legal framework for cooperation among nations, fostering sustainable and equitable management of shared ecosystems while supporting biodiversity. For instance, the UN Convention on the Law of the Sea (UNCLOS) governs marine biodiversity in areas beyond national jurisdiction, promoting the conservation and sustainable use of marine resources (Klein 2005). Similarly, the Ramsar Convention facilitates the protection of wetlands, including transboundary water systems essential for biodiversity (Stroud et al. 2022). Regional treaties have also proven effective in managing specific environmental challenges. The Convention on the Protection of the Mediterranean Sea Against Pollution, known as the Barcelona Convention, exemplifies collaborative frameworks that address pollution and habitat degradation in marine environments (Raftopoulos 1992; Montefalcone et al, 2021). In a related context, the Transboundary Freshwater Dispute Database 10 provides information on treaties across the world for more than 300 international river basins (McCracken and Wolf 2019). Turgul et al. (2024) provide an overview of major findings about transboundary water conflict and cooperation the last three decades. Since the 1960s, the environment has been increasingly highlighted in treaties (Giordano et al. 2014). However, Turgul et al. (2024), in their overview of major findings for transboundary water conflict and cooperation during the last three decades, note that more attention is needed to environmental issues. Several international river basin treaties incorporate biodiversity measurements or frameworks to monitor and 9 Roberson et al. (2021) point out that multinational coordination is required, especially for marine species, given that nearly all species in their sample span multiple national jurisdictions. 10 Product of the Transboundary Freshwater Diplomacy Database, College of Earth, Ocean, and Atmospheric Sciences, Oregon State University. Additional information about the TFDD can be found at: http://transboundarywaters.science.oregonstate.edu. 20 protect biodiversity. These measurements typically involve tracking the health of ecosystems, monitoring species populations, and assessing the impacts of water management activities. River basin organizations (RBOs) and treaties provide additional mechanisms for promoting cooperative management of shared waters while addressing threats like pollution, over- extraction, and habitat destruction. RBOs can play important roles in maintaining ecological balance, preserving biodiversity, and enhancing the resilience of critical ecosystems in the face of climate change and human-induced pressures. In the same vein, international river basin treaties can incorporate biodiversity considerations through monitoring species populations, ecosystem health, and habitat protection. Several important examples can be cited. (1) The Mekong Agreement integrates biodiversity monitoring into its Environment Programme, tracking species diversity, migration of fish (e.g., the Mekong giant catfish - Pangasianodon gigas), aquatic ecosystem health, and wetland conditions. The Agreement emphasizes the protection of wetlands and fisheries, along with sustainable species management. These goals reflect the broader vision of the Mekong River Commission (MRC), to ensure "an economically prosperous, socially just, environmentally sound, and climate resilient Mekong River Basin" (MRC, 2024). (2) The Nile Basin Initiative (NBI) includes biodiversity indicators to assess water management impacts on wetlands, ecosystems, and species. The NBI monitors pollution and focuses on the conservation of wetlands and aquatic ecosystems in water management plans. Critical species characteristics of the kind presented in Table 3 can play important roles in this context, including the identification of flagship species for Nile Basin wetland groups (NBI 2021). Article 6 of the Nile River Basin Cooperative Framework focuses on the protection and conservation of the Basin, including protecting and conserving biological diversity (NBI 2010). The NBI 10-Year Strategy identifies environmental sustainability as one of its six strategic priorities (Goal 4). (3) The Amazon Cooperation Treaty Organization (ACTO) promotes biodiversity conservation through monitoring forest, river, and wildlife status. Indicators include deforestation rates, species diversity, and ecosystem conditions. The Amazon Environmental Information Network (RAISG) tracks biodiversity and land-use trends, supporting sustainable resource management. (4) The Zambezi River Basin's Shared Vision (2004) integrates biodiversity monitoring into the Zambezi River Action Plan. The Zambezi River Authority (ZRA) monitors wetland health, riparian vegetation and fish populations, with a focus on migratory and endemic species (e.g. Kafue Lechwe, an endemic species of antelope in ZAMCOM 2008). The treaty advocates for integrated management to conserve ecosystems, limit pollution, and protect endangered species. While these river basin initiatives have made indispensable contributions (Petersen-Perlman et al. 2017), further improvements are possible. For example, Liu et al. (2020) find that transboundary conservation efforts have predominantly concentrated on large mammals, often overlooking other species. Better information would also help, since a key element in the successful implementation of the treaties is the availability of reliable and comparable data for biodiversity monitoring, habitat assessments, and cross-border implementation. Reliable data underpin early warning systems, foster evidence-based decision-making, and inform the coordination of conservation efforts across borders. Moreover, such data are vital in addressing 21 the impacts of climate change and human activities, where unilateral actions may have unintended transboundary effects. In this context, we believe that GBIF data can play a critical role in expanding the information base for species that are critical for biodiversity conservation. As noted above, a major result of our species-mapping project has been a greatly expanded view of occurrence regions for invertebrates and plants that are endemic, inhabit small regions, or confront elevated extinction threats. The effectiveness of biodiversity protection can only be enhanced by introducing this information into the design and implementation of transboundary treaties, river basin initiatives, and stabilization measures for fragile/conflict states. Biodiversity and natural resources also offer a unique, neutral platform for dialogue and confidence-building between divided groups, as evidenced by several cases worldwide. The Nile Basin Initiative encourages dialogue among Nile River countries, promoting integrated water resource management and sustainable development. The "Peace Parks" in Southern Africa, transboundary conservation areas like the Great Limpopo Transfrontier Park, have been created to promote peace and cooperation among Mozambique, South Africa, and Zimbabwe (Wolmer 2003). By focusing on shared environmental objectives, such initiatives help to build trust, reduce historical tensions, and foster a sense of shared responsibility among nations that may have previously experienced conflict. Similarly, in the Middle East, environmental issues have provided common ground for dialogue among Israelis, Palestinians, and Jordanians. Through initiatives like the Red Sea-Dead Sea Water Conveyance Project and joint efforts to rehabilitate the Jordan River, environmental peacebuilding has emerged as a valuable tool for fostering cooperation and understanding (Aggestam and Sundell 2016; Markel, Alster and Beyth 2013). Recently, a report by the World Bank (2022) 11 has highlighted biodiversity as a valuable entry point for intergroup dialogue and cooperation. Again, however, reliable and comparable biodiversity data are critical for the success of such initiatives. Accurate data can provide common ground for all stakeholders by promoting a clear understanding of biodiversity status, trends, and threats. Such information helps depoliticize discussions by focusing on objective information that can serve collaborative activities. Consistent and comparable data can also support effective monitoring and evaluation of biodiversity initiatives, ensuring that progress can be measured and adjusted as needed. Conclusion Given the unprecedented loss of biodiversity, it is essential for every country and territory to engage in conservation efforts to minimize further degradation and its impact on human well- being. Consistent, dependable, location-specific biodiversity data are crucial for identifying species at risk, monitoring environmental changes and informing policy decisions. These factors 11 https://www.worldbank.org/en/topic/environment/publication/defueling-conflict-environment-and- natural-resource-management-as-a-pathway-to-peace 22 are particularly important in critical biodiversity areas that span national borders and fragile/conflict regions. The estimates derived from GBIF data presented in this paper can serve as a valuable baseline for initiatives to address such problems. As thousands of new reports are added daily to the GBIF repository, a steadily-expanding inventory of up-to-date species occurrence maps can provide a critical, objective information resource for tracking biodiversity trends, evaluating conservation progress, and developing effective policies. This critical information can also provide more general benefits, because initiatives that focus on biodiversity can serve as valuable entry points for general dialogue and confidence-building among divided groups, fostering collaboration towards shared goals with multiple benefits (such as peace dividends). Threats to natural resources, including biodiversity loss, may be less politically sensitive and overlapping than other issues, and can encourage stakeholders to consider long-term perspectives on issues that transcend political boundaries. Finally, we should re-emphasize the importance of new species knowledge in this context. This exercise has shown that the GBIF data can support a large expansion of information about species (particularly invertebrates and plants) that have critical importance for biodiversity conservation because they are endemic, inhabit small areas, or face serious extinction threats. While past transboundary and fragile/conflict state initiatives have made important contributions to environmental protection, they can be enhanced by moving beyond the traditional focus on vertebrate species to a much broader set of species that warrant protection. Data Availability The data can be downloaded from https://datacatalog.worldbank.org/search/dataset/0066034/global_biodiversity_data For a related blog, see Bridging Conflicts and Protecting Global Biodiversity 23 References Aggestam, K., & Sundell, A. (2016). Depoliticizing water conflict: functional peacebuilding in the Red Sea–Dead Sea Water Conveyance project. Hydrological Sciences Journal, 61(7), 1302-1312. Anh, N. T. K. (2021). 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