Hydro-economic modeling of climate change impacts in Ethiopia

Ethiopia is susceptible to frequent climate extremes such as disastrous droughts and floods. These disastrous climatic events, which have caused significant adverse effects on the country’s economy and society, are expected to become more pronounced in the future under climate change. To identify the potential threat of climate change to the Ethiopian economy, this study analyzes three major factors that are changing under global warming: water availability under higher temperatures and changing precipitation patterns, the impact of changing precipitation patterns on flooding, and the potential impact on crop production of the carbon dioxide (CO2) fertilization effect. These issues are analyzed based on an existing multi-market-sector model for the Ethiopian economy, with a focus on agriculture. Our analysis finds that the major impact of climate change on Ethiopia’s economy will result from more frequent occurrence of extreme hydrologic events, which cause losses in both the agricultural and nonagricultural sectors. To adapt to these long-term changes, Ethiopia should invest in enhanced water control to expand irrigation and improve flood protection.carbon dioxide (CO2) fertilization effect, Climate change, Droughts, floods, Global warming, hydro-economic modeling, hydrologic events,

Evaluation of Fluvial Geomorphic Responses to the Removal of Dams with the Consideration of Hydrological Uncertainty: a Case Study in Shihgang Dam

Source: ICHE Conference Archive - https://mdi-de.baw.de/icheArchive

Hydro-economic modeling of climate change impacts in Ethiopia

Ethiopia is susceptible to frequent climate extremes such as disastrous droughts and floods. These disastrous climatic events, which have caused significant adverse effects on the country's economy and society, are expected to become more pronounced in the future under climate change. To identify the potential threat of climate change to the Ethiopian economy, this study analyzes three major factors that are changing under global warming: water availability under higher temperatures and changing precipitation patterns, the impact of changing precipitation patterns on flooding, and the potential impact on crop production of the carbon dioxide (CO2) fertilization effect. These issues are analyzed based on an existing multi-market-sector model for the Ethiopian economy, with a focus on agriculture. Our analysis finds that the major impact of climate change on Ethiopia's economy will result from more frequent occurrence of extreme hydrologic events, which cause losses in both the agricultural and nonagricultural sectors. To adapt to these long-term changes, Ethiopia should invest in enhanced water control to expand irrigation and improve flood protection.Non-PRIFPRI1; GRP22EPT

Hydro-Economic Modeling Projections

Two factors critical to assuring food security, whether at the local or the global level, are increasing crop productivity and increasing access to sustainable water supplies. These factors are also vital to the economic success of agriculture, which is particu­larly important in Ethiopia given that the sector accounts for about 41 percent of the country’s gross domestic product (GDP), produces 80 percent of its exports, employs 80 percent of the labor force, and is a major source of income and subsistence for the nation’s poor.Non-PRIFPRI1EPT

Flood Inundation Assessment Considering Hydrologic Conditions and Functionalities of Hydraulic Facilities

This study proposed a two-phase risk analysis scheme for flood management considering flood inundation losses, including: (1) simplified qualitative-based risk analysis incorporating the principles of failure mode and effect analysis (FMEA) to identify all potential failure modes associated with candidate flood control measures, to formulate a remedial action plan aiming for mitigating the inundation risk within an engineering system; and (2) detailed quantitative-based risk analysis to employ numerical models to specify the consequences including flood extent and resulting losses. Conventional qualitative-based risk analysis methods have shown to be time-efficient but without quantitative information for decision making. However, quantitative-based risk analysis methods have shown to be time- and cost- consuming for a full spectrum investigation. The proposed scheme takes the advantages of both qualitative-based and quantitative-based approaches of time-efficient, cost-saving, objective and quantitative features for better flood management in term of expected loss. The proposed scheme was applied to evaluate the Chiang-Yuan Drainage system located on Lin-Bien River in southern Taiwan, as a case study. The remedial action plan given by the proposed scheme has shown to greatly reduce the inundation area in both highlands and lowlands. These measures was investigated to reduce the water volume in the inundation area by 0.2 million cubic meters, even in the scenario that the flood recurrence interval exceeded the normal (10-year) design standard. Our results showed that the high downstream water stage in the downstream boundary may increase the inundation area both in downstream and upstream and along the original drainage channel in the vicinity of the diversion. The selected measures given by the proposed scheme have shown to substantially reduce the flood risk and resulting loss, taking account of various scenarios: short duration precipitation, decreased channel conveyance, pump station failure and so forth