Your search found 28 records
1 Hurst, C. 1984. A model of an Indian village: A study of alternative sources of energy for irrigation. World Development, 12(2):141-156.
(Location: IWMI HQ Call no: P 7947 Record No: H040370)
2 Brauch, H. G.; Spring, U. O.; Grin, J.; Mesjasz, C.; Kameri-Mbote, P.; Behera, N. C.; Chourou, B.; Krummenacher, H. (Eds.) 2009. Facing global environmental change: environmental, human, energy, food, health and water security concepts. Heidelberg, Germany: Springer. 1586p. (Hexagon Series on Human and Environmental Security and Peace Vol. 4)
(Location: IWMI HQ Call no: 363.7 G000 BRA Record No: H043458)
(0.58 MB)
3 Mapedza, Everisto; Hagos, Fitsum; Deneke, T.; van Koppen, Barbara; Awulachew, Seleshi Bekele; Denekew, Aster. 2011. The political economy of irrigation in the Amhara Region of Ethiopia. [Abstract only]. In International Association for the Study of the Commons (IASC). 13th IASC Biennial International Conference on Sustaining Commons: Sustaining Our Future, Hyderabad, India, 10 - 14 January 2011. Book of abstracts. Mexico City, DF, Mexico: International Association for the Study of the Commons (IASC); Gujarat, India: Foundation for Ecological Security (FES). pp.138.
(Location: IWMI HQ Call no: e-copy only Record No: H044573)
(0.10 MB) (2.09MB)
Why do irrigation schemes designed to alleviate poverty fail? Globally, there have been several attempts to design sustainable irrigation systems as a means of alleviating poverty in developing countries. Years after the initial investment, most of the irrigation schemes are no longer operational or operate well below full potential. This paper is an attempt to draw lessons of experience on the institutional design of irrigation schemes which are more likely to contribute to sustainable irrigation schemes. This paper argues that sound irrigation systems have to be based on good irrigation engineering which further needs to be complemented by good institutional arrangements to manage the irrigation scheme sustainably. The role of a good understanding between hydraulic engineering and a deeper social and institutional understanding is often misunderstood or ignored. Schemes addressing the two components in irrigation are more likely to result in poverty alleviation in the Amhara Region of Ethiopia. The paper further argues that whilst the neat bureaucratic irrigation planning never materializes, there is a need to consider power inequities, gender and the broader political economy of irrigation.
4 Clement, Floriane; Banset, G.; Bharati, Luna. 2012. Rethinking development models and irrigation projects in Nepal. Hydro Nepal: Journal of Water, Energy and Environment, April:112-120. (Special issue on "Proceedings of National Conference on Water, Food Security and Climate Change in Nepal" with contributions by IWMI authors).
(Location: IWMI HQ Call no: IWMI Record No: H044829)
Despite decades of investment and institutional refinement, externally funded irrigation programs still exhibit low success rates and more particularly in countries facing institutional and political challenges. This paper aims at bringing fresh insights on the reasons for such shortcomings with the particular case study of a donor-sponsored program recently implemented in the Mid and Far Western Regions of Nepal. Findings indicate that the political situation and institutional system in Nepal have substantially affected the outcomes of the agricultural water management (AWM) interventions conducted by the program. Yet, beyond the influence of these contextual factors, two other (less acknowledged) mechanisms have contributed to create a gap between project objectives and outcomes: a) concepts commonly found in project documents and development discourses such as participation or empowerment are kept vague and ambiguous and lack an explicit recognition of power distribution; and b) the organizational system of many funding agencies tends to create incentives for project staff to show outcomes rather than to make impacts. These findings suggest that refining current models of AWM interventions is not sufficient to improve their achievements. A more radical shift is needed. A few avenues for change include to: 1) pay a greater attention to the meaning and operationalisation of common development concepts (e.g., rights based approach, empowerment or participation); 2) consider the way interventions affect power distribution among stakeholders, including communities; and 3) modify the organizational system of the funding agency to increase its downward accountability to targeted beneficiaries. To sum-up, we need to rethink development as a means of empowering governments and citizens rather than as a way to provide assistance.
(Location: IWMI HQ Call no: IWMI Record No: H044898)
(3.85 MB) (207MB)
The aim of the set of modules is to cover useful elements of AWM from estimating runoff at micro and small watershed level up to irrigated field water management. The modules thus aim at covering water availability estimnation, water control and management, soil-water-plant relationship, water lifting and conveyance and irrigation methods. Each module is divided into a number of chapters and illustrated with figures, tables charts and examples. The modules are also useful as a reference and teaching material at technical, vocational, educational, and training centres and as a field guide. The publication extensively use existing knowledge in the form of texts, figures, demonstration materials derived from various sources such as books, grey literature such as web material, reports, manuals etc. specifically they have immensely used materials from FAO, ICRISAT and IWMI documentations with or without citation to the specific references.
6 Shah, Tushaar; Singh, M. 2012. Indian accelerated sectoral development programs: what can water sector learn from power sector? IWMI-Tata Water Policy Research Highlight, 13. 7p.
(Location: IWMI HQ Call no: e-copy only Record No: H045274)
(309.6KB)
7 Global Water Intelligence (GWI). 2013. Global water market 2014: meeting the world's water and wastewater needs until 2018. Vol. 1. Oxford, UK: Media Analytics Ltd. 459p. + 1CD.
(Location: IWMI HQ Call no: 333.91 G000 GLO e-copy SF Record No: H046240)
(0.50 MB)
8 Pittock, J. 2014. Energy. In Grafton, R. Q.; Wyrwoll, P.; White, C.; Allendes, D. (Eds.). Global water: issues and insights. Canberra, Australia: Australian National University (ANU Press). pp.121-124.
(Location: IWMI HQ Call no: e-copy only Record No: H046553)
(0.10 MB)
(Location: IWMI HQ Call no: IWMI Record No: H046623)
(2 MB)
(Location: IWMI HQ Call no: 577 G178 BOH Record No: H047357)
(7.80 MB) (7.80 MB)
(Location: IWMI HQ Call no: e-copy only Record No: H047475)
(0.82 MB)
The existing reservoirs on the River Tana (Kenya) were mainly constructed for hydropower generation, with inadequate consideration of the long-term impacts on downstream livelihoods. We investigated the impacts of the reservoirs on people’s livelihoods downstream. The results showed a few positive impacts in the vicinity of the reservoirs and numerous negative impacts downstream (i.e. reduced flood-recess agriculture and floodplain pastoralism, and escalating resource-use conflicts). Inadequate stakeholders’ consultation during reservoir development was also observed. We recommend a detailed basin-wide socioeconomic assessment for future reservoir developments and controlled flood release to simulate the natural flow regime, thereby restoring indigenous flood-based livelihoods while retaining sufficient reserves for power generation.
(Location: IWMI HQ Call no: e-copy only Record No: H047596)
(2.12 MB)
Water is essential for electricity and heat production. This study assesses the consumptive water footprint (WF) of electricity and heat generation per world region in the three main stages of the production chain, i.e. fuel supply, construction and operation. We consider electricity from power plants using coal, lignite, natural gas, oil, uranium or biomass as well as electricity from wind, solar and geothermal energy and hydropower. The global consumptive WF of electricity and heat is estimated to be 378 billion m3 per year. Wind energy (0.2–12 m3 TJe -1 ), solar energy through PV (6–303 m3 TJe -1 ) and geothermal energy (7–759 m3 TJe -1 ) have the smallest WFs, while biomass (50 000–500 000 m3 TJe -1 ) and hydropower (300–850 000 m3 TJe -1 ) have the largest. The WFs of electricity from fossil fuels and nuclear energy range between the extremes. The global weighted-average WF of electricity and heat is 4241 m3 TJe -1 . Europe has the largest WF (22% of the total), followed by China (15%), Latin America (14%), the USA and Canada (12%), and India (9%). Hydropower (49%) and firewood (43%) dominate the global WF. Operations (global average 57%) and fuel supply (43%) contribute the most, while the WF of construction is negligible (0.02%). Electricity production contributes 90% to the total WF, and heat contributes 10%. In 2012, the global WF of electricity and heat was 1.8 times larger than that in 2000. The WF of electricity and heat from firewood increased four times, and the WF of hydropower grew by 23%. The sector's WF can be most effectively reduced by shifting to greater contributions of wind, PV and geothermal energy.
(Location: IWMI HQ Call no: e-copy only Record No: H047912)
(0.51 MB)
Ethiopia is currently one of the fastest growing economies in Africa. Due to this rapid growth in economy the country is facing a huge challenge to meet the fast growing energy demand. The major demand comes from industrial, agricultural, service sectors and from the rising household consumption because of the rising standard of living. From among the many other sources of energy, the country identified hydropower to be the key to satisfy the current growing energy demand. When the government decided to develop huge hydropower projects on the country’s major river basins, it not only considered the country’s huge hydropower potential but also the additional social, economic and environmental benefits these multi-purpose hydropower projects bring. These hydropower projects also provide the opportunity to mitigate their minimal negative environmental impacts. This paper will explore the country’s hydropower potential, energy consumption, and future energy demand. Then it discusses the role of hydropower in terms of satisfying the energy demand and the advantages it provides as compared to other alternative energy technologies. Finally, the part hydropower plays in leading the country into a more sustainable energy future is explored as well.
(Location: IWMI HQ Call no: IWMI Record No: H048081)
(3 MB)
(Location: IWMI HQ Call no: e-copy only Record No: H048591)
(0.46 MB)
Biomass energy still dominates the energy sector in Sub-Saharan Africa, in particular as the main cooking energy source in rural and urban areas. The strong linkages to food security and the environment place biomass energy at the heart of sustainable development, a fact that is largely ignored by policy makers in favor of modern energy. At the same time, population and GDP growth are exacerbating already existing supply–demand imbalances in highly populated countries such as Malawi. These trends make it imperative to identify policy interventions that promote sustainable biomass energy while simultaneously considering linkages with other sectors. We use new data on demand and supply for biomass energy in Malawi and develop a model that estimates fuelwood demand based on actual diets and project demand in future years. We simulate how demand side interventions in the form of improved cookstoves affect biomass demand and built a behavioral model to analyze the potential of agroforestry for promoting a sustainable biomass energy sector in Malawi. Our findings show that policy measures aimed at increasing cooking efficiency are not enough to decrease demand for cooking energy due to high population growth. Supply side interventions like agroforestry on the other hand will not only increase sustainable supply, but can also enhance food security and protect the environment. We find that biomass energy can be inherently sustainable and should be an integral part of every energy sector strategy in developing countries as well as of the Sustainable Development Goals.
(Location: IWMI HQ Call no: e-copy only Record No: H048912)
(1.52 MB)
Water issues are receiving increasing attention from policy-makers and international organizations due to water scarcity and global rising demand. Given that the demand for water is mainly driven by agriculture and energy, we use a multifactor market model to analyze the impact of agriculture and energy price trends on the price of listed companies operating in the water industry. Evidence highlights a sensitivity of water stocks returns to agriculture and energy price changes. Additionally, when using state space model to estimate dynamic beta coefficients, factor sensitivities show a time-varying behavior, especially during the 2008 economic and financial crisis.
17 Gebrezgabher, Solomie; Amewu, S.; Njenga, M. 2018. Adoption and economic impact of briquettes as cooking fuel: the case of women fish smokers in Ghana. In Njenga, M.; Mendum, R. (Eds.). Recovering bioenergy in Sub-Saharan Africa: gender dimensions, lessons and challenges. Colombo, Sri Lanka: International Water Management Institute (IWMI). CGIAR Research Program on Water, Land and Ecosystems (WLE). pp.25-31. (Resource Recovery and Reuse: Special Issue)
(Location: IWMI HQ Call no: e-copy only Record No: H049000)
(468 KB)
18 Romania, M.; Njenga, M.; Mendum, R. 2018. Gender as key in community participation. In Njenga, M.; Mendum, R. (Eds.). Recovering bioenergy in Sub-Saharan Africa: gender dimensions, lessons and challenges. Colombo, Sri Lanka: International Water Management Institute (IWMI). CGIAR Research Program on Water, Land and Ecosystems (WLE). pp.69-71. (Resource Recovery and Reuse: Special Issue)
(Location: IWMI HQ Call no: e-copy only Record No: H049008)
(639 KB)
(Location: IWMI HQ Call no: e-copy only Record No: H049059)
(1.50 MB)
This article addresses the emergence and interrelation of food, energy, and water security in terms of resource use and the ensuing societal and environmental outcomes. For decades, food security and energy security have been well-accepted, operational concepts. Water security is the latest entrant, yet the implications of water insecurity for food, energy and earth systems resilience have not been adequately considered. This article examines how and why this is so – particularly with growing water scarcity and insecurity that may compete with energy and food security – and emphasizes the critical need to link water-energy-food nexus approaches to earth systems resilience.
(Location: IWMI HQ Call no: IWMI Record No: H049196)
(1.28 MB)
The increasing demand for water, energy and food, and the interdependence of these systems could lead to potential human conflict in the future. This was seen in the food crisis of 2008, which stirred a renewed interest in taking a "systems" approach to managing resources. The initial flurry of activities led to many nexus frameworks, but there remains a gap between theory and its implementation. This paper tries to look at various frameworks and unpacks the concept of nexus in order to develop matrices to help quantify and understand the interlinkages between the nexus systems. It suggests multi-level and multi-system indices to measure the health of nexus systems and to identify the weak links. It is hoped that such frameworks can be used at country level, and eventually be used to measure and rank countries on the health of their systems. The paper suggests a questionnaire that can be used (after modifying for local conditions) to collect country-level institutional and political-economy data (which is difficult to get from online resources) to be used in the framework.
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