Impact of land use and land cover change in river flow and hydro-energy generation: The case of Bagmati basin in central Nepal

IF 8 Q1 ENERGY & FUELS Energy nexus Pub Date : 2024-05-15 DOI:10.1016/j.nexus.2024.100305

Suraj Lamichhane, Nirajan Devkota, Tek Raj Subedi, Arun Bikram Thapa

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Abstract

The hydrological dynamics of the Bagmati River downstream from Kathmandu have transformed due to rapid urbanization, impacting regional water projects. Declining open land and groundwater levels have reduced winter base flow and increased summer peak discharge, challenging sustainable energy generation. This study quantifies Land Use and Land Cover (LULC) impact on downstream hydropower. Using LULC data and a calibrated hydrological model in SWAT, it introduces change scenarios, analyzing their influence on river runoff and energy generation. Results reveal varied runoff curve numbers and seasonal discharge due to LULC shifts. Annual mean flow sees a 1.3% increase, while lean flow decreases by 3.45%. Consequently, dry, wet, and total energy generation drops annually by 0.68%, 0.31%, and 0.38%, respectively. The Flow Duration Curve (FDC) notably shifts upwards at its top and downwards at the bottom compared to the base simulation, defining the most sustainable installed capacity. Additionally, the study presents a regression equation based on LULC changes for simplified analysis. It underscores the crucial role of LULC modifications in river runoff, profoundly impacting energy generation and water resource projects' sustainability. Neglecting these changes could severely affect project success.

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土地利用和土地覆盖变化对河流流量和水力发电的影响：尼泊尔中部巴格马蒂流域的案例

由于快速城市化，加德满都下游巴格马蒂河的水文动态发生了变化，对地区水利工程产生了影响。开阔地和地下水位的下降导致冬季基本流量减少，夏季峰值流量增加，给可持续能源生产带来了挑战。本研究量化了土地利用和土地覆被 (LULC) 对下游水电的影响。利用 LULC 数据和 SWAT 中的校准水文模型，该研究引入了各种变化情景，分析它们对河流径流和发电量的影响。结果显示，由于 LULC 的变化，径流曲线数和季节性排水量也发生了变化。年平均流量增加了 1.3%，而枯水期流量减少了 3.45%。因此，干流、湿流和总发电量每年分别下降 0.68%、0.31% 和 0.38%。与基础模拟相比，流量持续时间曲线（FDC）的顶部明显上移，底部明显下移，从而确定了最可持续的装机容量。此外，研究还提出了一个基于 LULC 变化的回归方程，以简化分析。它强调了 LULC 变化在河流径流中的关键作用，对能源发电和水资源项目的可持续性产生了深远影响。忽视这些变化会严重影响项目的成功。

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来源期刊

Energy nexus Energy (General), Ecological Modelling, Renewable Energy, Sustainability and the Environment, Water Science and Technology, Agricultural and Biological Sciences (General)

CiteScore

7.70

自引率

0.00%

发文量

审稿时长

109 days