Your search found 7 records
1 Sander, B. O.; Wassmann, R.; Siopongco, J. D. L. C. 2015. Mitigating greenhouse gas emissions from rice production through water-saving techniques: potential, adoption and empirical evidence. In Hoanh, Chu Thai; Johnston, Robyn; Smakhtin, Vladimir. Climate change and agricultural water management in developing countries. Wallingford, UK: CABI. pp.193-207. (CABI Climate Change Series 8)
Greenhouse gases ; Methane emission ; Nitrous oxide ; Crop production ; Flood irrigation ; Rice ; Water conservation ; Water management ; Farmers ; Wet season ; Dry season
(Location: IWMI HQ Call no: IWMI Record No: H047379)
(599 KB)
2 Mohammed, M.; Egyir, I. S.; Donkor, A. K.; Amoah, Philip; Nyarko, S.; Boateng, K. K.; Ziwu, C. 2017. Feasibility study for biogas integration into waste treatment plants in Ghana. Egyptian Journal of Petroleum, 26(3):695-703. [doi: https://doi.org/10.1016/j.ejpe.2016.10.004]
Feasibility studies ; Biogas ; Integration ; Waste treatment ; Sewerage ; Renewable energy ; Cost benefit analysis ; Economic aspects ; Investment ; Methane emission ; Electricity generation / Ghana
(Location: IWMI HQ Call no: e-copy only Record No: H047916)
http://ac.els-cdn.com/S1110062116300940/1-s2.0-S1110062116300940-main.pdf?_tid=f5e92158-c823-11e6-984a-00000aacb362&acdnat=1482396925_bdef0d40b3893e4ea6d337f2ccc6815b
https://vlibrary.iwmi.org/pdf/H047916.pdf
https://vlibrary.iwmi.org/pdf/H047916.pdf
(1.57 MB)
Biogas (anaerobic digestion) technology is one of the most viable renewable energy technologies today. However, its economic efficiency depends on the investment costs, costs of operating the biogas plant and optimum methane production. Likewise the profit level also rests on its use directly for cooking or conversion into electricity. The present study assessed the economic potential for a 9000 m3 biogas plant, as an alternative to addressing energy and environmental challenges currently in Ghana. A cost-benefit analysis of the installation of biogas plant at University of Ghana (Legon Sewerage Treatment Plant) yielded positive net present values (NPV) at the prevailing discount rate of 23%. Further the results demonstrate that installation of the plant is capital intensive. Biogas used for cooking was by far the most viable option with a payback period (PBP) of 5 years. Sensitivity analysis also revealed cost of capital, plant and machinery as the most effective factors impacting on NPV and internal rate of return (IRR).
3 Hosen, Y. 2016. Development of agricultural technologies in the Mekong Delta to respond to climate change. Ibaraki, Japan: Japan International Research Center for Agricultural Sciences. 105p. (JIRCAS Working Report 84)
Climate change ; Agricultural development ; Technological changes ; Rice ; Deltas ; Wet cultivation ; Dry farming ; Methane emission ; Emission reduction ; Carbon dioxide ; Carbon credits ; Biogas ; Greenhouse gases ; Households ; Feeding habits ; Grazing ; Flooding ; Environmental effects ; Water conservation ; Livestock ; Cattle ; Ruminants ; Nutrients ; Carbohydrases ; Tannins ; Fish culture ; Economic aspects ; Evapotranspiration / Southeast Asia / Vietnam / Mekong Delta
(Location: IWMI HQ Call no: 630 G784 HOS Record No: H047936)
4 Janz, B.; Weller, S.; Kraus, D.; Racela, H. S.; Wassmann, R.; Butterbach-Bahl, K.; Kiese, R. 2019. Greenhouse gas footprint of diversifying rice cropping systems: impacts of water regime and organic amendments. Agriculture, Ecosystems and Environment, 270-271:41-54. [doi: https://doi.org/10.1016/j.agee.2018.10.011]
Greenhouse gas emissions ; Cropping systems ; Irrigation water ; Organic amendments ; Rice straw ; Agronomic practices ; Crop rotation ; Diversification ; Mung beans ; Maize ; Catch crops ; Methane emission ; Nitrous oxide ; Climatic change ; Green manures ; Residues / Philippines
(Location: IWMI HQ Call no: e-copy only Record No: H049124)
(3.06 MB)
Increasing water scarcity and Asia’s rapid economic and social development, specifically the growing demand for animal products and biofuels, is forcing farmers to transform their traditional lowland double-rice cropping systems [R-R] to mixed lowland-upland systems where upland crops such as aerobic rice [R-A] or maize [R-M] are grown instead of paddy rice during the dry period. Such changes have implications on the C and N cycling in the soil-plant system, including major shifts in soil greenhouse gas (GHG) emissions from CH4 to N2O once paddies are used for upland cropping. Moreover, soil organic carbon stocks are decreasing, thereby jeopardizing soil fertility. In this study, we investigated if straw residue incorporation and/or catch crop cultivation impairs the greenhouse gas footprint of diversifying rice cropping systems and thus, presents an alternative to open-field straw burning and intensive mineral N fertilization. For this, we calculate annual global warming potentials (GWP) and yield-scaled GWPs of three different rice systems (R-R: rice-rice, R-A: rice- aerobic rice, R-M: rice maize) without (control) or with additions of straw (+6 Mg ha-1 [S]) or + straw + mungbean as catch crop ([M + S]) on the basis of high-temporal-resolution GHG emissions (CH4 and N2O), and measurements of yield parameters. The field trial was carried out at the International Rice Research Institute (IRRI), Philippines, covering two full years. Although dry season N2O emissions increased twice- to threefold in the diversified systems (R-A, R-M), the strong reduction of CH4 emissions during this period resulted in significantly lower annual yield-scaled GWP as compared to the traditional R-R system. The same pattern was observed after application and incorporation of organic material (straw and mungbean), but led to higher substrate availability for methanogens during the following season. Therefore, the GWP was 9–39% higher in treatments including straw incorporation as compared to a control treatment without organic substrate amendments. Additional incorporation of mungbeans further increased GWPs, whereby the increment was highest in R-R rotation (88%) and lowest in R-M rotation (55%), with annual GHG emissions of 11.8 and 5.6 Mg CO2-eq ha-1, respectively. Our study shows that the yield-scaled GWP, as well as irrigation water demand, is lowest for rice-maize (R-M) cropping systems, followed by R-A and R-R systems. This ranking persists even with the incorporation of crop residues, a requirement for farmers as the ban of open-field burning is increasingly enforced. Our work also calls for a refinement of IPCC emission factors for lowland-upland rotations and the inclusion of the land-preparation period within the GHG balance of rice cropping systems.
5 Islam, S. M. M.; Gaihre, Y. K.; Islam, Md. R.; Ahmed, Md. N.; Akter, M.; Singh, U.; Sander, B. O. 2022. Mitigating greenhouse gas emissions from irrigated rice cultivation through improved fertilizer and water management. Journal of Environmental Management, 307:114520. (Online first) [doi: https://doi.org/10.1016/j.jenvman.2022.114520]
Irrigated rice ; Greenhouse gas emissions ; Emission reduction ; Irrigated farming ; Water management ; Global warming ; Fertilizers ; Nitrous oxide ; Methane emission ; Urea ; Use efficiency ; Crop management ; Integrated plant nutrient management / Bangladesh / Gazipur
(Location: IWMI HQ Call no: e-copy only Record No: H050888)
https://www.sciencedirect.com/science/article/pii/S0301479722000937/pdfft?md5=0eaa9b512d6b0a05efd7497c1b19b265&pid=1-s2.0-S0301479722000937-main.pdf
https://vlibrary.iwmi.org/pdf/H050888.pdf
https://vlibrary.iwmi.org/pdf/H050888.pdf
(0.91 MB) (928 KB)
Greenhouse gas (GHG) emissions from agriculture sector play an important role for global warming and climate change. Thus, it is necessary to find out GHG emissions mitigation strategies from rice cultivation. The efficient management of nitrogen fertilizer using urea deep placement (UDP) and the use of the water-saving alternate wetting and drying (AWD) irrigation could mitigate greenhouse gas (GHG) emissions and reduce environmental pollution. However, there is a dearth of studies on the impacts of UDP and the integrated plant nutrient system (IPNS) which combines poultry manure and prilled urea (PU) with different irrigation regimes on GHG emissions, nitrogen use efficiency (NUE) and rice yields. We conducted field experiments during the dry seasons of 2018, 2019, and 2020 to compare the effects of four fertilizer treatments including control (no N), PU, UDP, and IPNS in combination with two irrigation systems— (AWD and continuous flooding, CF) on GHG emissions, NUE and rice yield. Fertilizer treatments had significant (p < 0.05) interaction effects with irrigation regimes on methane (CH4) and nitrous oxide (N2O) emissions. PU reduced CH4 and N2O emissions by 6% and 20% compared to IPNS treatment, respectively under AWD irrigation, but produced similar emissions under CF irrigation. Similarly, UDP reduced cumulative CH4 emissions by 9% and 15% under AWD irrigation, and 9% and 11% under CF condition compared to PU and IPNS treatments, respectively. Across the year and fertilizer treatments, AWD irrigation significantly (p < 0.05) reduced cumulative CH4 emissions and GHG intensity by 28%, and 26%, respectively without significant yield loss compared to CF condition. Although AWD irrigation increased cumulative N2O emissions by 73%, it reduced the total global warming potential by 27% compared to CF irrigation. The CH4 emission factor for AWD was lower (1.67 kg ha-1 day-1) compared to CF (2.33 kg ha-1 day-1). Across the irrigation regimes, UDP increased rice yield by 21% and N recovery efficiency by 58% compared to PU. These results suggest that both UDP and AWD irrigation might be considered as a carbon-friendly technology.
6 Matsuda, S.; Nakamura, K.; Hung, T.; Quang, L. X.; Horino, H.; Hai, P. T.; Ha, N. D.; Hama, T. 2022. Paddy ponding water management to reduce methane emission based on observations of methane fluxes and soil redox potential in the Red River Delta, Vietnam. Irrigation and Drainage, 71(1):241-254. [doi: https://doi.org/10.1002/ird.2645]
Water management ; Paddy fields ; Ponding ; Methane emission ; Greenhouse gases ; Soil ; Redox potential ; Deltas ; Water conservation ; Irrigation ; Water levels ; Flooding ; Evapotranspiration / South East Asia / Vietnam / Red River Delta
(Location: IWMI HQ Call no: e-copy only Record No: H051040)
(2.85 MB)
Reducing methane (CH4) emissions from paddy fields that contribute to the greenhouse effect has been addressed recently through the application of the alternate wetting and drying irrigation method. However, in poorly drained areas, such as the Red River Delta in Vietnam, the soil cannot be dried immediately, and so CH4 can continue to be produced unintentionally. Therefore, the purpose of this case study was to identify the optimal ponding water management schedule to reduce CH4 emissions by using the measured data of ponding depth, soil redox potential (Eh), and CH4 fluxes from field experiments and to show its effects on CH4 emission and water conservation. Observations in the winter–spring cropping season showed that the non-flooding period of 3–8 days suppressed CH4 emission, and the continuous flooding period of 14–22 days caused CH4 re-emission. Information regarding the non-flooding period to be maintained and the flooding period to be avoided to suppress CH4 emission was not obtained for the summer–autumn cropping season due to abundant rainfall. The proposed schedule could suppress CH4 emission by 27%–85% and increase the amount of conserved water by up to 18% compared with traditional flooding protocols, but it may increase irrigation water due to the frequency and the amount of re-flooding.
7 Epule, T. E.; Chehbouni, A.; Ongoma, V.; Brouziyne, Youssef; Etongo, D.; Molua, E. L. 2022. A new index on agricultural land greenhouse gas emissions in Africa. Environmental Monitoring and Assessment, 194(9):598. [doi: https://doi.org/10.1007/s10661-022-10196-4]
Greenhouse gas emissions ; Agricultural land ; Carbon dioxide ; Methane emission ; Nitrous oxide ; Climate change adaptation ; Climate change mitigation ; Vulnerability ; Spatial distribution ; Time series analysis / North Africa / West Africa / Middle Africa / East Africa / Southern Africa
(Location: IWMI HQ Call no: e-copy only Record No: H051387)
(1.27 MB)
Africa emits the lowest amounts of greenhouse gases (GHGs) into the global GHG budget. However, the continent remains the most vulnerable continent to the effects of climate change. The agricultural sector in Africa is among the most vulnerable sectors to climate change. Also, as a dominant agricultural sector, African agriculture is increasingly contributing to climate change through GHG emissions. Research has so far focused on the effects of GHG emissions on the agricultural and other sectors with very little emphasis on monitoring and quantifying the spatial distribution of GHG emissions from agricultural land in Africa. This study develops a new index: African Agricultural Land Greenhouse Gas Index (AALGGI) that uses scores and specific scale ranges for carbon dioxide (CO2), methane (CH4), and nitrous oxide (N2O) to map the spatial variations in regional GHG emissions across Africa. The data for the three main GHGs (CO2, CH4, and N20) were downloaded from FAOSTAT. The data were analyzed through the newly developed African Agricultural Land Greenhouse Gas Index (AALGGI). This is an empirical index with scores ranging from 0 to 10, with higher scores indicating higher levels of emissions. The results show that Southern and North African regions have the lowest amounts of agricultural land GHG emissions, with AALGGIs of 3.5 and 4.5, respectively. East Africa records the highest levels of GHG emissions, with an AALGGI of 8 followed by West Africa with an AALGGI of 7.5. With the continental mean or baseline AALGGI being 5.8, East and Middle Africa are above the mean AALGGI. These results underscore the fact that though Africa, in general, is not a heavy emitter of GHGs, African agricultural lands are increasingly emitting more GHGs into the global GHG budget. The low AALGGIs in the more developed parts of Africa such as Southern and North Africa are explained by their domination in other GHG emitting sectors such as industrialization and energy. The high rates of emissions in East Africa and Middle Africa are mainly linked to intensive traditional farming practices/processes and deforestation. These findings underscore the need to further leverage climate change mitigation actions and policy in Africa and most importantly the co-benefits of mitigation and adaptations in the most vulnerable regions.
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