Difference between revisions of "Climate-Smart Agrifood Systems: Publications"
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<span class="link3">[[Systemes_agroalimentaires_respectueux_du_climat_:_Publications|►French Version]]</span><br/> | <span class="link3">[[Systemes_agroalimentaires_respectueux_du_climat_:_Publications|►French Version]]</span><br/> | ||
{{Back to PA portal2}} | {{Back to PA portal2}} | ||
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= <span style="color:#00A3AD">Sustainable Energy for Food</span><br/> = | = <span style="color:#00A3AD">Sustainable Energy for Food</span><br/> = | ||
*<span class="reference-text">[https://docs.wbcsd.org/2014/05/Co-op_Summary.pdf World Business Council for Sustainable Development (2014). Co-optimizing Solutions: Water and Energy for Food, Feed and Fiber.]</span><br/> | *<span class="reference-text">[https://docs.wbcsd.org/2014/05/Co-op_Summary.pdf World Business Council for Sustainable Development (2014). Co-optimizing Solutions: Water and Energy for Food, Feed and Fiber.]</span><br/> | ||
− | *[https://www.irena.org/publications/ | + | *[https://www.irena.org/publications/2015/Jan/Renewable-Energy-in-the-Water-Energy--Food-Nexus IRENA (2015). Renewable Energy in the Water, Energy & Food Nexus] |
*[[:File:Opportunities for Agri-Food Chains to become Energy-Smart.pdf|Powering Agriculture (2015). Opportunities for Agri-Food Chains to become Energy-Smart]]. | *[[:File:Opportunities for Agri-Food Chains to become Energy-Smart.pdf|Powering Agriculture (2015). Opportunities for Agri-Food Chains to become Energy-Smart]]. | ||
*[https://gc21.giz.de/ibt/var/app/wp385P/2624/wp-content/uploads/2015/03/170202_PA_MOOC_Reader.pdf GIZ (2016). Sustainable Energy for Food - Massive Open Online Course - Reader].<br/> | *[https://gc21.giz.de/ibt/var/app/wp385P/2624/wp-content/uploads/2015/03/170202_PA_MOOC_Reader.pdf GIZ (2016). Sustainable Energy for Food - Massive Open Online Course - Reader].<br/> | ||
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*[[Publication - The Market Opportunity for Productive Use Leveraging Solar Energy (PULSE) in Sub-Saharan Africa|World Bank (2019). The Market Opportunity for Productive Use Leveraging Solar Energy (PULSE) in Sub-Saharan Africa]] | *[[Publication - The Market Opportunity for Productive Use Leveraging Solar Energy (PULSE) in Sub-Saharan Africa|World Bank (2019). The Market Opportunity for Productive Use Leveraging Solar Energy (PULSE) in Sub-Saharan Africa]] | ||
*[[Publication - Technology Case Study: Clean Energy Agro-Processing|Powering Agriculture (2020). Technology Case Study: Clean Energy Agro-Processing]] | *[[Publication - Technology Case Study: Clean Energy Agro-Processing|Powering Agriculture (2020). Technology Case Study: Clean Energy Agro-Processing]] | ||
+ | *[https://rmi.org/wp-content/uploads/2021/01/nigeria_power_sector_program.pdf USAID Power Africa (2020). Agricultural productive use stimulation in Nigeria: Value chain & mini-grid feasibility study] | ||
== <span style="color:#00A3AD">Gender Aspects</span><br/> == | == <span style="color:#00A3AD">Gender Aspects</span><br/> == | ||
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<br/> | <br/> | ||
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= <span style="color:#00A3AD">Water Use in Agriculture</span><br/> = | = <span style="color:#00A3AD">Water Use in Agriculture</span><br/> = | ||
*[http://www.fao.org/assets/infographics/FAO-Infographic-water-thirsty-en.pdf FAO. The World is Thirsty ...]<br/> | *[http://www.fao.org/assets/infographics/FAO-Infographic-water-thirsty-en.pdf FAO. The World is Thirsty ...]<br/> | ||
− | *[https://www.un-igrac.org/ | + | *[https://www.un-igrac.org/news/igrac-strategy-2019-23-groundwater-changing-world IGRAC (2019). Groundwater in a Changing World.]<br/> |
*[http://www.fao.org/3/a-i4591e.pdf FAO. Irrigation Management.]<br/> | *[http://www.fao.org/3/a-i4591e.pdf FAO. Irrigation Management.]<br/> | ||
− | *<span style="text-align: left; | + | *<span style="text-align: left; color: rgb(48, 48, 48); text-transform: none; text-indent: 0px; letter-spacing: normal; font-family: arial,helvetica,clean,sans-serif; font-size: 13px; font-style: normal; font-variant: normal; font-weight: 400; text-decoration: none; word-spacing: 0px; float: none; display: inline !important; white-space: normal; orphans: 2; background-color: transparent; -webkit-text-stroke-width: 0px"></span>[https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2935123/ Strzepek, K., & Boehlert, B. (2010). Competition for water for the food system. Philosophical transactions of the Royal Society of London. Series B, Biological sciences, 365(1554).]<br/> |
− | *<span style="text-align: left; | + | *<span style="text-align: left; color: rgb(0, 0, 0); text-transform: none; text-indent: 0px; letter-spacing: normal; font-family: verdana; font-size: 12px; font-style: normal; font-variant: normal; font-weight: 400; text-decoration: none; word-spacing: 0px; float: none; display: inline !important; white-space: normal; orphans: 2; background-color: transparent; -webkit-text-stroke-width: 0px"></span>[http://www.iwmi.cgiar.org/assessment/Publications/books.htm David Molden and IWMI (2007). Water for Food, Water for Life. Earthscan.]<br/> |
*[https://www.oecd-ilibrary.org/agriculture-and-food/navigating-pathways-to-reform-water-policies-in-agriculture_906cea2b-en;jsessionid=vUSipLXv1ogLW5y3O7ZdLUAx.ip-10-240-5-165 Gruère, G. and H. Le Boëdec (2019). Navigating pathways to reform water policies in agriculture. OECD Food, Agriculture and Fisheries Papers, No. 128, OECD Publishing, Paris.]<br/> | *[https://www.oecd-ilibrary.org/agriculture-and-food/navigating-pathways-to-reform-water-policies-in-agriculture_906cea2b-en;jsessionid=vUSipLXv1ogLW5y3O7ZdLUAx.ip-10-240-5-165 Gruère, G. and H. Le Boëdec (2019). Navigating pathways to reform water policies in agriculture. OECD Food, Agriculture and Fisheries Papers, No. 128, OECD Publishing, Paris.]<br/> | ||
*[http://www.fao.org/3/a-i4560e.pdf FAO and World Water Council (2015). Towards a Water and Food Secure Future – Critical Perspectives for Policy-Makers.]<br/> | *[http://www.fao.org/3/a-i4560e.pdf FAO and World Water Council (2015). Towards a Water and Food Secure Future – Critical Perspectives for Policy-Makers.]<br/> | ||
*[http://www.fao.org/3/ca5789en/ca5789en.pdf Field Guide to Improve Water use Efficiency in Small-Scale-Agriculture: The case of Burkina Faso, Morocco and Uganda.]<br/> | *[http://www.fao.org/3/ca5789en/ca5789en.pdf Field Guide to Improve Water use Efficiency in Small-Scale-Agriculture: The case of Burkina Faso, Morocco and Uganda.]<br/> | ||
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= <span style="color:#00A3AD">Application</span><br/> = | = <span style="color:#00A3AD">Application</span><br/> = | ||
− | == <span style="color: | + | |
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+ | == <span style="color: rgb(0, 163, 173);">Pumping and Irrigation</span><br/> == | ||
*[https://energypedia.info/images/3/32/Case_Study_Kenya-_Ongata_Rongai.pdf Country Case Study Ongata-Rongai (Kenya): Hydroponics]<br/> | *[https://energypedia.info/images/3/32/Case_Study_Kenya-_Ongata_Rongai.pdf Country Case Study Ongata-Rongai (Kenya): Hydroponics]<br/> | ||
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*[https://energypedia.info/images/8/88/Pompage_Solaire.pdf GIZ (2019). Investigation de l’impact des installations de pompage solaire sur la consommation d’eau et la situation socio- économique d’un agriculteur dans 3 zones pilotes au Maroc.]<br/> | *[https://energypedia.info/images/8/88/Pompage_Solaire.pdf GIZ (2019). Investigation de l’impact des installations de pompage solaire sur la consommation d’eau et la situation socio- économique d’un agriculteur dans 3 zones pilotes au Maroc.]<br/> | ||
*[https://www.pseau.org/outils/ouvrages/practica_foundation_unicef_le_pompage_solaire_applique_aux_adductions_d_eau_potable_en_milieu_rural_manuel_de_formation_2018.pdf UNICEF (2019). Le Pompage Solaire. Appliqué aux Adductions d’Eau Potable en milieu rural. Manuel de Formation.]<br/> | *[https://www.pseau.org/outils/ouvrages/practica_foundation_unicef_le_pompage_solaire_applique_aux_adductions_d_eau_potable_en_milieu_rural_manuel_de_formation_2018.pdf UNICEF (2019). Le Pompage Solaire. Appliqué aux Adductions d’Eau Potable en milieu rural. Manuel de Formation.]<br/> | ||
− | *[[Publication - Solar Pumping: The Basics|World Bank (2018).Solar Pumping: The Basics]] | + | *[[Publication - Solar Pumping: The Basics|World Bank (2018). Solar Pumping: The Basics]]<br/> |
+ | |||
+ | *[https://energypedia.info/images/7/74/Solar_Powered_Irrigation_Systems_%28SPIS%29_-_Technology%2C_Economy%2C_Impacts.pdf GIZ (2020). Solar Powered Irrigation Systems (SPIS) - Technology, Economy, Impacts]<br/> | ||
<br/> | <br/> | ||
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== <span style="color:#00A3AD">Cooling</span><br/> == | == <span style="color:#00A3AD">Cooling</span><br/> == | ||
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**[[Media:Costs and Benefits of Clean Energy Technologies in Kenyas Milk Value Chain.pdf|Costs and Benefits of Clean Energy Technologies in Kenya's Milk Value Chain]] | **[[Media:Costs and Benefits of Clean Energy Technologies in Kenyas Milk Value Chain.pdf|Costs and Benefits of Clean Energy Technologies in Kenya's Milk Value Chain]] | ||
**[[Media:Costs and Benefits of Clean Energy Technologies in Tunisia’s Milk Value Chain.pdf|Costs and Benefits of Clean Energy Technologies in Tunisia’s Milk Value Chain]] | **[[Media:Costs and Benefits of Clean Energy Technologies in Tunisia’s Milk Value Chain.pdf|Costs and Benefits of Clean Energy Technologies in Tunisia’s Milk Value Chain]] | ||
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*[http://www.fao.org/fileadmin/user_upload/ivc/PDF/SFVC/Tanzania_rice.pdf FAO (2015). The Rice Value Chain in Tanzania. A Report from the Southern Highlands Food Systems Programme.]<br/> | *[http://www.fao.org/fileadmin/user_upload/ivc/PDF/SFVC/Tanzania_rice.pdf FAO (2015). The Rice Value Chain in Tanzania. A Report from the Southern Highlands Food Systems Programme.]<br/> | ||
*[https://webdoc.agsci.colostate.edu/smallholderagriculture/RiceValueChain.pdf Winrock International (2012). Rice Value Chain Analysis – Sokoto State Nigeria.]<br/> | *[https://webdoc.agsci.colostate.edu/smallholderagriculture/RiceValueChain.pdf Winrock International (2012). Rice Value Chain Analysis – Sokoto State Nigeria.]<br/> | ||
− | *<span class="selectable" id="js-reference-string-0" style="color: rgb(0, 0, 0)"></span>[ | + | *<span class="selectable" id="js-reference-string-0" style="color: rgb(0, 0, 0)"></span>[https://bit.ly/3pOC5UE Nidagundi, A. and Mulimani, R. (2017). Design and Fabrication of Solar Paddy Threshing Machine for Agriculture Purpose. International Journal of Innovative and Emerging Research in Engineering, 4(10).]<br/> |
− | * | + | *[https://pdf.usaid.gov/pdf_docs/PA00WRT5.pdf FAO (2018). Costs and Benefits of Clean Energy Technologies in the Philippines’ Rice Value Chain.] |
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== <span style="color:#00A3AD">Fruit and Vegetables</span><br/> == | == <span style="color:#00A3AD">Fruit and Vegetables</span><br/> == | ||
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= <span style="color:#00A3AD">Energy Efficiency</span><br/> = | = <span style="color:#00A3AD">Energy Efficiency</span><br/> = | ||
− | *[[ | + | *[[Energy_Efficiency_in_Agrifood_Systems#Energy_Efficiency_Potentials_in_the_Kenyan_Tea_Sector|Energy Efficiency Potentials in the Kenyan Tea Sector – Reducing Energy Consumption at Tea Processing Factories]] |
<br/> | <br/> | ||
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− | *[https://www.reeep.org/sites/default/files/REEEP_Making_The_Case.pdf REEEP and FAO (2014): Making the Case: How Agrifood Firms are Building New Business Cases in the Water-Energy-Food Nexus]''<span style="text-align: left; | + | = <span style="color: rgb(0, 163, 173);">Financing and Business Models</span><br/> = |
+ | |||
+ | *[https://www.reeep.org/sites/default/files/REEEP_Making_The_Case.pdf REEEP and FAO (2014): Making the Case: How Agrifood Firms are Building New Business Cases in the Water-Energy-Food Nexus]''<span style="text-align: left; color: rgb(0, 0, 0); text-transform: none; text-indent: 0px; letter-spacing: normal; font-family: arial,helvetica; font-size: 13.6px; font-style: normal; font-variant: normal; font-weight: 400; text-decoration: none; word-spacing: 0px; float: none; display: inline !important; white-space: normal; orphans: 2; background-color: transparent; -webkit-text-stroke-width: 0px;">.</span>''<br/> | ||
*'''INVESTA Project '''<br/> | *'''INVESTA Project '''<br/> | ||
**[[:File:Costs and Benefits of Clean Energy Technologies in the Milk, Vegetable and Rice Value Chains.pdf|FAO (2018). The Costs and benefits of clean energy technologies in the milk, vegetable and rice value chains.]]<br/> | **[[:File:Costs and Benefits of Clean Energy Technologies in the Milk, Vegetable and Rice Value Chains.pdf|FAO (2018). The Costs and benefits of clean energy technologies in the milk, vegetable and rice value chains.]]<br/> | ||
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*'''INVESTA Policy Briefs'''<br/> | *'''INVESTA Policy Briefs'''<br/> | ||
− | **[http://www.fao.org/3/i8017en/I8017EN.pdf FAO (2018). Costs and Benefits of Clean | + | **[http://www.fao.org/3/i8017en/I8017EN.pdf FAO (2018). Costs and Benefits of Clean Energy Technologies in the Milk, Vegetable and Rice Value Chains.]<br/> |
− | **[ | + | **[http://www.fao.org/3/i9058en/I9058EN.pdf FAO (2018). Costs and Benefits of Clean Energy Technologies in Kenya’s Vegetable Value Chain.]<br/> |
− | **[http://www.fao.org/3/ | + | **[http://www.fao.org/3/i9040en/I9040EN.pdf FAO (2018). Costs and Benefits of Clean Energy Technologies in the Philippines’ Rice Value Chain.]<br/> |
− | **[ | + | **[http://www.fao.org/3/ca2209en/CA2209EN.pdf FAO (2018). Costs and Benefits of Solar Irrigation Systems in Senegal] |
*[http://www.fao.org/fileadmin/templates/tci/pdf/RuralInvestBrochure_en.pdf FAO. RuralInvest – A Participatory Approach to Identifying and Preparing Small/Medium Scale Agricultural and Rural Investments.]<br/> | *[http://www.fao.org/fileadmin/templates/tci/pdf/RuralInvestBrochure_en.pdf FAO. RuralInvest – A Participatory Approach to Identifying and Preparing Small/Medium Scale Agricultural and Rural Investments.]<br/> | ||
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**[[Publication - Access to Financing for Early-Stage Innovators in the Clean Energy-Agriculture Nexus|Access to Financing for Early-Stage Innovators in the Clean Energy-Agriculture Nexus (2020)]] | **[[Publication - Access to Financing for Early-Stage Innovators in the Clean Energy-Agriculture Nexus|Access to Financing for Early-Stage Innovators in the Clean Energy-Agriculture Nexus (2020)]] | ||
+ | [[Category:Powering_Agriculture]] | ||
[[Category:Water-Energy-Food_Nexus]] | [[Category:Water-Energy-Food_Nexus]] | ||
− |
Latest revision as of 07:28, 18 January 2021
►Back to the WE4F Portal |
Sustainable Energy for Food
- World Business Council for Sustainable Development (2014). Co-optimizing Solutions: Water and Energy for Food, Feed and Fiber.
- IRENA (2015). Renewable Energy in the Water, Energy & Food Nexus
- Powering Agriculture (2015). Opportunities for Agri-Food Chains to become Energy-Smart.
- GIZ (2016). Sustainable Energy for Food - Massive Open Online Course - Reader.
- IRENA (2016). Renewable Energy Benefits - Decentralised Solutions in Agri Food-Chains.
- FAO (2016). How Access to Energy can Influence Food Losses: A Brief Overview
- FAO (2019).Climate-smart agriculture and the Sustainable Development Goals: Mapping interlinkages, synergies and trade-offs and guidelines for integrated implementation.
- World Bank (2019). The Market Opportunity for Productive Use Leveraging Solar Energy (PULSE) in Sub-Saharan Africa
- Powering Agriculture (2020). Technology Case Study: Clean Energy Agro-Processing
- USAID Power Africa (2020). Agricultural productive use stimulation in Nigeria: Value chain & mini-grid feasibility study
Gender Aspects
Water Use in Agriculture
- FAO. The World is Thirsty ...
- IGRAC (2019). Groundwater in a Changing World.
- FAO. Irrigation Management.
- Strzepek, K., & Boehlert, B. (2010). Competition for water for the food system. Philosophical transactions of the Royal Society of London. Series B, Biological sciences, 365(1554).
- David Molden and IWMI (2007). Water for Food, Water for Life. Earthscan.
- Gruère, G. and H. Le Boëdec (2019). Navigating pathways to reform water policies in agriculture. OECD Food, Agriculture and Fisheries Papers, No. 128, OECD Publishing, Paris.
- FAO and World Water Council (2015). Towards a Water and Food Secure Future – Critical Perspectives for Policy-Makers.
- Field Guide to Improve Water use Efficiency in Small-Scale-Agriculture: The case of Burkina Faso, Morocco and Uganda.
Application
Pumping and Irrigation
- Country Case Study Ongata-Rongai (Kenya): Hydroponics
- Country Case Study Chile – La Tirana
- Country Case Study India –Lalpura
- Country Case Study Holgojo Farm (Kenya)
- Country Case Study Alaoui (Morocco)
- IRENA (2016). Solar Pumping for Irrigation: Improving Livelihoods and Sustainability.
- FAO and GIZ (2018). The Benefits and Risks of Solar-Powered Irrigation: An Overview.
- FAO (2018). Costs and Benefits of Solar Irrigation Systems in Senegal
- GIZ (2019). Investigation de l’impact des installations de pompage solaire sur la consommation d’eau et la situation socio- économique d’un agriculteur dans 3 zones pilotes au Maroc.
- UNICEF (2019). Le Pompage Solaire. Appliqué aux Adductions d’Eau Potable en milieu rural. Manuel de Formation.
- World Bank (2018). Solar Pumping: The Basics
Cooling
- GIZ (2018). Implications of natural refrigerants for cooling technologies.
- REEEP (2017). Clean Energy Solutions for Milk Cooling in India and Kenya.
Drying
Other Type of Food Processing
Energy Source
Solar Power
- Solar Powered Irrigation Country Case Study Chile – La Tirana.
- Country Case Study India –Lalpura.
- Country Case Study Holgojo Farm (Kenya).
- Country Case Study Alaoui (Morocco).
- IRENA (2016). Solar Pumping for Irrigation: Improving Livelihoods and Sustainability.
- FAO and GIZ (2018). The Benefits and Risks of Solar-Powered Irrigation: An Overview.
- GIZ (2019). Investigation de l’impact des installations de pompage solaire sur la consommation d’eau et la situation socio- économique d’un agriculteur dans 3 zones pilotes au Maroc.
- UNICEF (2019). Le Pompage Solaire. Appliqué aux Adductions d’Eau Potable en milieu rural. Manuel de Formation.
- Solar Water Pump Outlook 2019: Global Trends and Market Opportunities
Solar Powered Cooling
- Costs and Benefits of Clean-Energy-Technologies in the Milk Value Chain:
Solar Drying
- Solar Rice Dryer
- Coffee Processing with Solar Dryers in Peru
- Drying Peaches with Solar Dryers in Bolivia
Other Solar Powered Applications
Biomass / Biogas
- World Bank Group (2019). Have Improved Cookstoves Benefitted Rural Kenyans?
- Bioenergy for Agricultural Production.
Wind and Hydro Power
Geothermal
Value Chains
Dairy
- ICFN and FAO (2010). Pro-Poor Livestock Policy Initiative. Status and Prospects for Smallholder Milk Production: A Global Perspective.
- Costs and Benefits of Clean-Energy-Technologies in the Milk Value Chain:
Rice
- FAO (2015). The Rice Value Chain in Tanzania. A Report from the Southern Highlands Food Systems Programme.
- Winrock International (2012). Rice Value Chain Analysis – Sokoto State Nigeria.
- Nidagundi, A. and Mulimani, R. (2017). Design and Fabrication of Solar Paddy Threshing Machine for Agriculture Purpose. International Journal of Innovative and Emerging Research in Engineering, 4(10).
- FAO (2018). Costs and Benefits of Clean Energy Technologies in the Philippines’ Rice Value Chain.
Fruit and Vegetables
- Solar-Powered Oil Press for Sesame Seed
- F. Joosten, Y. Dijkxhoorn, Y. Sertse and R.Ruben. How Does the Fruit and Vegetable Sector contribute to Food and Nutrition Security?
Tea
- KTDA, ETP and Strathmore University (2019). Training Package Thermal.
- KTDA, ETP and Strathmore University (2019). Training Package Electrical.
Energy Efficiency
Financing and Business Models
- REEEP and FAO (2014): Making the Case: How Agrifood Firms are Building New Business Cases in the Water-Energy-Food Nexus.
- INVESTA Project
- INVESTA Policy Briefs
- FAO (2018). Costs and Benefits of Clean Energy Technologies in the Milk, Vegetable and Rice Value Chains.
- FAO (2018). Costs and Benefits of Clean Energy Technologies in Kenya’s Vegetable Value Chain.
- FAO (2018). Costs and Benefits of Clean Energy Technologies in the Philippines’ Rice Value Chain.
- FAO (2018). Costs and Benefits of Solar Irrigation Systems in Senegal
- FAO (2018). Costs and Benefits of Clean Energy Technologies in the Milk, Vegetable and Rice Value Chains.