Your search found 33 records
1 Moreau, J. (Ed.) 1997. Advances in the ecology of Lake Kariba. Harare, Zimbabwe: University of Zimbabwe Publications. 271p.
Lakes ; Ecology ; Ecosystems ; Hydrology ; Water quality ; Nutrients ; Chlorophylls ; Nitrogen fixation ; Phytoplankton ; Zooplankton ; Invertebrates ; Aquatic environment ; Fisheries / Africa / Zimbabwe / Zambia / Zambezi River / Lake Kariba
(Location: IWMI-HQ Call no: 577.63 G100 MOR Record No: H039342)
2 Lancaster, J.; Belyea, L. R. 1997. Nested hierarchies and scale-dependence of mechanisms of flow refugium use. Journal of the North American Benthological Society, 16(1):221-238.
(Location: IWMI-HQ Call no: P 7767 Record No: H039725)
3 Baran, E.; Chheng, P.; Warry, F.; Toan, V. T.; Hung, H. P.; Hoanh, Chu Thai. 2010. Aquatic resources and environmental variability in Bac Lieu Province (southern Vietnam). In Hoanh, Chu Thai; Szuster, B. W.; Kam, S. P.; Ismail, A. M; Noble, Andrew D. (Eds.). Tropical deltas and coastal zones: food production, communities and environment at the land-water interface. Wallingford, UK: CABI; Colombo, Sri Lanka: International Water Management Institute (IWMI); Penang, Malaysia: WorldFish Center; Los Banos, Philippines: International Rice Research Institute (IRRI); Bangkok, Thailand: FAO Regional Office for Asia and the Pacific; Colombo, Sri Lanka: CGIAR Challenge Program on Water and Food (CPWF). pp.13-32. (Comprehensive Assessment of Water Management in Agriculture Series 9)
Aquatic environment ; Aquatic organisms ; Fisheries ; Salinity ; Sluices ; Coastal area / Southern Vietnam / Bac Lieu Province
(Location: IWMI HQ Call no: IWMI 551.457 G000 HOA Record No: H043038)
http://www.iwmi.cgiar.org/Publications/CABI_Publications/CA_CABI_Series/Coastal_Zones/protected/9781845936181.pdf
https://vlibrary.iwmi.org/pdf/H043038.pdf
https://vlibrary.iwmi.org/pdf/H043038.pdf
(1.60 MB) (5.08 MB)
The dynamics of aquatic resources in the canals of Bac Lieu Province, in southern Vietnam, are detailed and synthesized in this study. Nekton and eight environmental parameters were monitored in this province between 2004 and 2006, at 14 sites sampled three times a year. The study area, located along the coastal zone, is characterized by a variable environment subject to saline, freshwater and acidic pulses. The spatiotemporal dynamics of aquatic resources and their relationships with environmental parameters are detailed. The dominance of either freshwater or estuarine fauna, the dynamics of assemblages and the catches of fishers appear to be largely influenced by the management of sluice gates built along the coastal zone.
4 Finlayson, M.; Atapattu, Sithara S. 2009. Unit nine - Water and ecosystems. [Training/Course material]. In Smith, L. (Ed.). C126 - Water resources management. 10 units. [Training/Course material]. London, UK: University of London. School of Oriental and African Studies (SOAS); Centre for Development, Environment and Policy (CeDEP); Colombo, Sri Lanka: International Water Management Institute (IWMI). 48p.
Water resource management ; Ecosystems ; Aquatic environment ; Ecology ; Natural resources ; Biodiversity ; Wetlands ; Environmental flows
(Location: IWMI HQ Call no: CD Col. Record No: H043425)
(1.41 MB)
This unit provides an introduction to the key concepts and issues associated with managing water for ecosystems. ‘Aquatic ecosystems’ is a wide term that includes a range of inland, coastal and marine ecosystems but for the purpose of this module we will concentrate on inland and coastal aquatic ecosystems. Section 1 begins by outlining the natural resources provided by ecosystems and linkages with poverty by identifying the interdependencies and the importance of water. Section 2 details the ecology of aquatic ecosystems and their structure, processes and biodiversity. Section 3 takes a further step and describes the ecosystem services provided by these ecosystems. Section 4 looks at the over-exploitation of the services provided by aquatic ecosystems and how this can lead to ecosystem degradation. The final section concludes the unit by summarising scenarios and management response options. This unit includes an extended listing of recommendations for further reading with brief commentaries on each. These can extend study for the core topics of this unit but also cut across many of the topics covered in earlier units, given the linkages and interdependencies between water for nature and other human uses of water. Students should review the commentaries on these readings but only use this extended listing of reading as a resource to pursue specific interests as far as time allows. Concentration of study on the unit text and recommended Key Readings is sufficient for the examinations. Unit aims: To introduce the concept of natural resources with water being an important resource that supports both the livelihoods of the rural poor and aquatic ecosystems, whilst understanding their inter-linkages and interdependencies; To introduce key concepts of aquatic ecology by describing the variations and structure, the processes, species and genes, and inter-linkages; To introduce the concept of ‘ecosystem services’ in the context of aquatic ecosystems and to describe the role these play in maintaining the resource as well as supporting livelihoods of the rural poor; To provide an understanding of the key drivers of degradation and impacts on aquatic ecosystems and to describe available assessment tools and identify management approaches.
5 Stewart, B. A.; Woolhiser, D. A.; Wischmeier, W. H.; Caro, J. H.; Frere, M. H.; Alt, K. F. 1976. Control of water pollution from cropland. Vol 2 - An overview. Washington, DC, USA: U.S. Environmental Protection Agency; Hyattsville, MD, USA: U. S. Department of Agriculture. 187p.
Water pollution ; Farmland ; Hydrological cycle ; Models ; Agricultural practices ; Rain ; Runoff ; Erosion ; Sediment transport ; Sedimentation ; Nutrients ; Leaching ; Soil conservation ; Agricultural wastes ; Fertilizers ; Pesticides ; Aquatic environment ; Economic aspects
(Location: IWMI HQ Call no: 333.91 G000 STE Record No: H043857)
(0.08 MB)
6 Abal, E. G.; Bunn, S. E.; Dennison, W. C. (Eds.) 2005. Healthy waterways, healthy catchments: making the connection in south east Queensland, Australia. Brisbane, Australia: Moreton Bay Waterways and Catchments Partnership. 222p.
Water quality ; Catchment areas ; Aquatic environment ; Watershed management ; Erosion ; Sedimentation ; Nutrients ; Ecosystems / Australia / South East Queensland
(Location: IWMI HQ Call no: 333.91 G922 ABA Record No: H045257)
(0.69 MB)
7 Bruch, C.; Jansky, L.; Nakayama, M.; Salewicz, K. A. (Eds.) 2005. Public participation in the governance of international freshwater resources. Tokyo, Japan: United Nations University Press. 506p. (Water Resources Management and Policy)
Water resources ; Water governance ; Public participation ; International waters ; Water law ; Watershed management ; Watercourses ; Water quality ; International agreements ; International organizations ; International cooperation ; Ecosystems ; Aquatic environment ; Stakeholders ; Decision support systems ; Environmental impact assessment / Central Europe / North America / USA / Canada / Thailand / South Africa / Senegal / Kenya / Southern Africa / Danube River / Mekong River Basin / Okavango River Basin / Senegal River basin / Chesapeake Bay / Delaware River / Great Lakes / Cirata Dam / Saguling Dam / Cirata Dam / Colorado River / Grand Canyon
(Location: IWMI HQ Call no: 333.91 G000 BRU Record No: H046475)
(0.36 MB)
8 Douthwaite, B.; Apgar, J. M.; Schwarz, A.; McDougall, C.; Attwood, S.; Senaratna Sellamuttu, Sonali; Clayton, T. 2015. Research in development: learning from the CGIAR Research Program on Aquatic Agricultural Systems. Penang, Malaysia: CGIAR Research Program on Aquatic Agricultural Systems. 96p. (CGIAR Research Program on Aquatic Agricultural Systems Working Paper: AAS-2015-16)
Development theory ; Agricultural research ; Less favoured areas ; Partnerships ; Gender ; Equity ; Women's participation ; Men ; Households ; Aquatic environment ; Ownership ; Community involvement ; Stakeholders ; Empowerment ; Floodplains ; Reclaimed land ; Farmers ; Fish culture ; Participatory approaches ; Social aspects ; Ecology ; Resource management ; Capacity building ; Case studies / Zambia / Bangladesh / Solomon Islands / Philippines / Cambodia / Barotse / Malaita / Visayas-Mindanao / Tonle Sap
(Location: IWMI HQ Call no: e-copy only Record No: H047452)
(2.58 MB)
9 Nawab, A.; Sinha, R. K.; Thompson, P. M.; Sharma, S. 2016. Ecosystem services and conservation assessment of freshwater biodiversity. In Bharati, Luna; Sharma, Bharat R.; Smakhtin, Vladimir (Eds.). The Ganges River Basin: status and challenges in water, environment and livelihoods. Oxon, UK: Routledge - Earthscan. pp.188-204. (Earthscan Series on Major River Basins of the World)
Freshwater ; Biodiversity conservation ; Ecosystem services ; Environmental protection ; Assessment ; Aquatic environment ; Species ; Invertebrates ; Fauna ; Fisheries ; Mangroves ; River basins ; Cultural behaviour / India / Bangladesh / Nepal / Ganga River
(Location: IWMI HQ Call no: IWMI Record No: H047843)
10 Bunting, S.W.; Luo, S.; Cai, K.; Kundu, N.; Lund, S.; Mishra, R.; Ray, D.; Smith, K. G.; Sugden, Fraser. 2016. Integrated action planning for biodiversity conservation and sustainable use of highland aquatic resources: evaluating outcomes for the Beijiang River, China. Journal of Environmental Planning and Management, 59(9):1580-1609. [doi: https://doi.org/10.1080/09640568.2015.1083414]
Integrated management ; Action plans ; Development plans ; Planning ; Biodiversity conservation ; Sustainability ; Highlands ; Aquatic environment ; Resource management ; Rivers ; Environmental management ; Wetlands ; Stakeholders ; Ecosystem services ; Living standards ; Policy making ; Strategic planning ; Implementation ; Monitoring ; Performance evaluation ; Socioeconomic environment ; Participatory approaches / China / India / Vietnam / Beijiang River
(Location: IWMI HQ Call no: e-copy only Record No: H047885)
The need for enhanced environmental planning and management for highland aquatic resources is described and a rationale for integrated action planning is presented. Past action planning initiatives for biodiversity conservation and wetland management are reviewed. A re ective account is given of integrated action planning from ve sites in China, India and Vietnam. Eight planning phases are described encompassing: stakeholder assessment and partner selection; rapport building and agreement on collaboration; integrated biodiversity, ecosystem services, livelihoods and policy assessment; problem analysis and target setting; strategic planning; planning and organisation of activities; coordinated implementation and monitoring; evaluation and revised target setting. The scope and targeting of actions are evaluated using the Driving forces, Pressures, State, Impacts and Responses framework and compatibility with biodiversity conservation and socio-economic development objectives are assessed. Criteria to evaluate the quality of planning processes are proposed. Principles for integrated action planning elaborated here should enable stakeholders to formulate plans to reconcile biodiversity conservation with the wise use of wetlands.
11 Joffre, O. M.; Castine, S. A.; Phillips, M. J.; Senaratna Sellamuttu, Sonali; Chandrabalan, D.; Cohen, P. 2017. Increasing productivity and improving livelihoods in aquatic agricultural systems: a review of interventions. Food Security, 9(1):39-60. [doi: https://doi.org/10.1007/s12571-016-0633-3]
Aquatic environment ; Agricultural systems ; Living standards ; Productivity ; Food security ; Food demand ; Food production ; Nutrition ; Participatory approaches ; Income ; Intensification ; Floodplains ; Community involvement ; Fisheries ; Rice ; Livestock ; Horticulture ; Case studies / Bangladesh / Cambodia / Zambia
(Location: IWMI HQ Call no: e-copy only Record No: H047944)
The doubling of global food demand by 2050 is driving resurgence in interventions for agricultural intensification. Globally, 700 million people are dependent on floodplain or coastal systems. Increased productivity in these aquatic agricultural systems is important for meeting current and future food demand. Agricultural intensification in aquatic agricultural systems has contributed to increased agricultural production, yet these increases have not necessarily resulted in broader development outcomes for those most in need. Here we review studies of interventions that have sought to improve productivity in aquatic agricultural systems in Bangladesh, Cambodia and Zambia. We review evidence of development outcomes from these interventions and the particular role of participatory approaches in intervention design and deployment. There was evidence of increases in productivity in 20 of the 31 studies reviewed. Yet, productivity was only measured beyond the life of the intervention in one case, income and food security improvements were rarely quantified, and the social distribution of benefits rarely described. Participatory approaches were employed in 15 studies, and there was some evidence that development outcomes were more substantial than in cases that were less participatory. To explore the impact of participatory approaches further, we examined five empirical cases. Review and empirical cases provide preliminary evidence suggesting participatory approaches contribute to ensuring agriculture and aquaculture interventions into aquatic agricultural systems may better fit local contexts, are sustained longer, and are more able to deliver development benefits to those most in need. A worthy focus of future research would be comparison between outcomes achieved from interventions with differing levels of participation, and the social differentiation of outcomes.
12 Apgar, J. M.; Cohen, P. J.; Ratner, B. D.; de Silva, Sanjiv; Buisson, Marie-Charlotte; Longley, C.; Bastakoti, Ram C.; Mapedza, Everisto. 2017. Identifying opportunities to improve governance of aquatic agricultural systems through participatory action research. Ecology and Society, 22(1):1-13. [doi: https://doi.org/10.5751/ES-08929-220109]
Aquatic environment ; Agricultural systems ; Equity ; Participatory approaches ; Collective action ; Research ; Governance ; Authorities ; Resource management ; Floodplains ; Living standards ; Ownership ; Stakeholders ; Accountability ; Ecological factors / Zambia / Solomon Islands / Bangladesh / Cambodia
(Location: IWMI HQ Call no: e-copy only Record No: H047980)
http://www.ecologyandsociety.org/vol22/iss1/art9/ES-2016-8929.pdf
https://vlibrary.iwmi.org/pdf/H047980.pdf
https://vlibrary.iwmi.org/pdf/H047980.pdf
(156 KB)
Challenges of governance often constitute critical obstacles to efforts to equitably improve livelihoods in social-ecological systems. Yet, just as often, these challenges go unspoken, or are viewed as fixed parts of the context, beyond the scope of influence of agricultural, development, or natural resource management initiatives. What does it take to get governance obstacles and opportunities out in the open, creating the space for constructive dialogue and collective action that can help to address them? We respond to this question by comparing experiences of participatory action research (PAR) in coastal and floodplain systems in four countries (Zambia, Solomon Islands, Bangladesh, and Cambodia) with a focus on understanding how to build more equitable governance arrangements. We found that governance improvement was often an implicit or secondary objective of initiatives that initially sought to address more technical natural resource or livelihood-related development challenges. We argue that using PAR principles of ownership, equity, shared analysis, and feedback built trust and helped to identify and act upon opportunities to address more difficult-to-shift dimensions of governance particularly in terms of stakeholder representation, distribution of authority, and accountability. Our findings suggest that the engaged and embedded approach of researcher-facilitators can help move from identifying opportunities for governance change to supporting stakeholders as they build more equitable governance arrangements.
13 Douthwaite, B.; Apgar, J. M.; Schwarz, A.-M.; Attwood, S.; Senaratna Sellamuttu, Sonali; Clayton, T. 2017. A new professionalism for agricultural research for development. International Journal of Agricultural Sustainability, 15(3):238-252. [doi: https://doi.org/10.1080/14735903.2017.1314754]
Agricultural research ; Research and development ; Professionalism ; Research organizations ; CGIAR ; Research programmes ; Aquatic environment ; Agricultural systems ; Participatory approaches ; Community involvement ; Partnerships ; Stakeholders ; Scientists ; Farmers ; Capacity building ; Gender equity ; Green revolution ; Case studies ; Monitoring ; Evaluation
(Location: IWMI HQ Call no: e-copy only Record No: H048130)
(1.39 MB)
There have been repeated calls for a ‘new professionalism’ for carrying out agricultural research for development since the 1990s. At the centre of these calls is a recognition that for agricultural research to support the capacities required to face global patterns of change and their implications on rural livelihoods, requires a more systemic, learning focused and reflexive practice that bridges epistemologies and methodologies. In this paper, we share learning from efforts to mainstream such an approach through a large, multi-partner CGIAR research program working in aquatic agricultural systems. We reflect on four years of implementing research in development (RinD), the program’s approach to the new professionalism. We highlight successes and challenges and describe the key characteristics that define the approach. We conclude it is possible to build a program on a broader approach that embraces multidisciplinarity and engages with stakeholders in social-ecological systems. Our experience also suggests caution is required to ensure there is the time, space and appropriate evaluation methodologies in place to appreciate outcomes different to those to which conventional agricultural research aspires.
14 Boelee, E.; Janse, J.; Le Gal, A.; Kok, M.; Alkemade, R.; Ligtvoet, W. 2017. Overcoming water challenges through nature-based solutions. Water Policy, 19(5):820-836. [doi: https://doi.org/10.2166/wp.2017.105]
Water shortage ; Integrated management ; Water resources ; Water management ; Ecosystems ; Aquatic environment ; Biodiversity ; Water use ; Water power ; Water pollution ; Flood control ; Food production ; Forecasting ; Sustainable development ; Ecological factors ; Barriers ; Models ; Urban areas
(Location: IWMI HQ Call no: e-copy only Record No: H048418)
(0.20 MB)
Freshwater is a key resource and medium for various economic sectors and domestic purposes but its use is often at the expense of natural ecosystems. Water management must change to deal with urgent issues and protect aquatic ecosystems and their services, while addressing the demand for water from the competing claims for cities, agriculture, industry, energy and transport. In this paper key water challenges (shortage, pollution, aquatic ecosystems threatened) have been identified via global modelling. By the IMAGE-GLOBIO model chain a Trend scenario up to 2050 was modelled, as well as the potential of three ‘pathways’ aimed at halving average global biodiversity loss while also meeting the sustainable development goals. Biodiversity is then used as a guiding principle to address these challenges because water services depend on healthy and biodiverse ecosystems. Subsequently the potential of nature-based solutions is reviewed for four sub-sectors: cities, food production, hydropower, and flood protection, grouped under the three alternative pathways to meet key water challenges. Mainstreaming biodiversity into water policy requires integrated planning. Integrated Water Resource Management (IWRM) could provide an opportune starting point as a well recognised integrating framework for planning, to guide the actual implementation of nature-based solutions in sub-sectors.
15 Douthwaite, B.; Hoffecker, E. 2017. Towards a complexity-aware theory of change for participatory research programs working within agricultural innovation systems. Agricultural Systems, 155:88-102. [doi: https://doi.org/10.1016/j.agsy.2017.04.002]
Agricultural research ; Participatory research ; Research programmes ; Agricultural innovation systems ; International organizations ; CGIAR ; Aquatic environment ; Agricultural systems ; Fisheries ; Stakeholders ; Scientists ; Farmers ; Evaluation ; Empowerment ; Case studies ; Plant fibres ; Abaca ; Models / Zambia / Philippines
(Location: IWMI HQ Call no: e-copy only Record No: H048508)
(0.83 MB)
Agricultural innovation systems (AIS) are increasingly recognized as complex adaptive systems in which interventions cannot be expected to create predictable, linear impacts. Nevertheless, the logic models and theory of change (ToC) used by standard-setting international agricultural research agencies and donors assume that agricultural research will create impact through a predictable linear adoption pathway which largely ignores the complexity dynamics of AIS, and which misses important alternate pathways through which agricultural research can improve system performance and generate sustainable development impact. Despite a growing body of literature calling for more dynamic, flexible and “complexity-aware” approaches to monitoring and evaluation, few concrete examples exist of ToC that takes complexity dynamics within AIS into account, or provide guidance on how such theories could be developed. This paper addresses this gap by presenting an example of how an empirically-grounded, complexity-aware ToC can be developed and what such a model might look like in the context of a particular type of program intervention. Two detailed case studies are presented from an agricultural research program which was explicitly seeking to work in a “complexity-aware” way within aquatic agricultural systems in Zambia and the Philippines. Through an analysis of the outcomes of these interventions, the pathways through which they began to produce impacts, and the causal factors at play, we derive a “complexity-aware” ToC to model how the cases worked. This middle-range model, as well as an overarching model that we derive from it, offer an alternate narrative of how development change can be produced in agricultural systems, one which aligns with insights from complexity science and which, we argue, more closely represents the ways in which many research for development interventions work in practice. The nested ToC offers a starting point for asking a different set of evaluation and research questions which may be more relevant to participatory research efforts working from within a complexity-aware, agricultural innovation systems perspective.
16 Ntiamoa-Baidu, Y.; Ampomah, B. Y.; Ofosu, E. A. (Eds.) 2017. Dams, development and downstream communities: implications for re-optimising the operations of the Akosombo and Kpong Dams in Ghana. Tema, Ghana: Digibooks Ghana Ltd. 466p.
Dams ; Downstream ; Community development ; Local communities ; Development projects ; Environmental flows ; Environmental impact ; River basin management ; Hydrology ; Fisheries ; Living standards ; Biodiversity ; Aquatic environment ; Aquatic weeds ; Groundwater recharge ; Rain ; Temperature ; Water power ; Energy generation ; Restoration ecology ; Socioeconomic environment ; Economic aspects ; Poverty ; Lakes ; Corporate culture ; Public health ; Drinking water ; Water supply ; Mapping ; Case studies / Ghana / Akosombo Dam / Kpong Dam / Lower Volta River / Volta Lake
(Location: IWMI HQ Call no: 627.8 G200 NTI Record No: H048570)
17 Mateo-Sagasta, Javier; Zadeh, S. M.; Unver, O.; De Souza, M.; Turral, H.; Burke, J. 2018. Setting the scene. In Mateo-Sagasta, Javier; Zadeh, S. M.; Turral, H. (Eds.). More people, more food, worse water?: a global review of water pollution from agriculture. Rome, Italy: FAO; Colombo, Sri Lanka: International Water Management Institute (IWMI). CGIAR Research Program on Water, Land and Ecosystems (WLE). pp.3-13.
Water pollution ; Agricultural wastes ; Crops ; Aquaculture ; Livestock ; Water quality ; Water scarcity ; Costs ; Sustainable development ; Aquatic environment
(Location: IWMI HQ Call no: e-copy only Record No: H048856)
(544 KB)
18 Mateo-Sagasta, Javier; Albers, J. 2018. Sediment. In Mateo-Sagasta, Javier; Zadeh, S. M.; Turral, H. (Eds.). More people, more food, worse water?: a global review of water pollution from agriculture. Rome, Italy: FAO; Colombo, Sri Lanka: International Water Management Institute (IWMI). CGIAR Research Program on Water, Land and Ecosystems (WLE). pp.111-123.
Sediment pollution ; Agriculture ; Soils ; Erosion ; Surface water ; Aquatic environment ; Sediment yield ; Turbidity ; Chemical contamination ; Reservoirs ; Rivers
(Location: IWMI HQ Call no: e-copy only Record No: H048860)
(604 KB)
19 Zandaryaa, S.; Mateo-Sagasta, Javier. 2018. Organic matter, pathogens and emerging pollutants. In Mateo-Sagasta, Javier; Zadeh, S. M.; Turral, H. (Eds.). More people, more food, worse water?: a global review of water pollution from agriculture. Rome, Italy: FAO; Colombo, Sri Lanka: International Water Management Institute (IWMI). CGIAR Research Program on Water, Land and Ecosystems (WLE). pp.125-138.
Water pollution ; Organic matter ; Pathogens ; Pollutant load ; Agricultural wastes ; Wastewater ; Surface water ; Water quality ; Public health ; Aquatic environment ; Livestock
(Location: IWMI HQ Call no: e-copy only Record No: H048861)
(680 KB)
20 Ligtvoet, W.; Bouwman, A.; Knoop, J.; de Bruin, S.; Nabielek, K.; Huitzing, H.; Janse, J.; van Minnen, J.; Gernaat, D.; van Puijenbroek, P.; de Ruiter, J.; Visser, H. 2018. The geography of future water challenges. Hague, Netherlands: PBL Netherlands Environmental Assessment Agency. 103p.
Water management ; Water stress ; Sustainable Development Goals ; Weather hazards ; Climate change ; Drought ; Flooding ; Disaster risk management ; Water pollution ; Wastewater treatment ; Drinking water ; Public health ; Sanitation ; Nutrients ; Energy generation ; Hydropower ; Dams ; Food production ; Crop yield ; Fuel crops ; Ecology ; Aquatic environment ; Ecosystems ; Freshwater ; Biodiversity ; Economic development ; Urbanization ; Migration ; Conflicts
(Location: IWMI HQ Call no: e-copy only Record No: H048887)
http://www.pbl.nl/sites/default/files/cms/publicaties/pbl-2018-the-geography-of-future-water-challenges-2920.pdf
https://vlibrary.iwmi.org/pdf/H048887.pdf
https://vlibrary.iwmi.org/pdf/H048887.pdf
(27.70 MB) (27.7 MB)
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