Assessment of Climate Change Impacts on the Precipitation and Temperature: A Case Study on Krishna River Basin, India

IF 1.4 4区地球科学 Q4 METEOROLOGY & ATMOSPHERIC SCIENCES

Russian Meteorology and Hydrology Pub Date : 2024-01-01 DOI:10.3103/s1068373924010084

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Abstract

In this study, the statistical downscaling model (SDSM) is employed for downscaling the precipitation (PREC), maximum temperature ( \(T_{\max}\) ), and minimum temperature ( \(T_{\min}\) ) over the Krishna River Basin (KRB). The Canadian Earth System Model, version 2 (CanESM2) General Circulation Model (GCM) outputs were considered as predictor variables. First, the SDSM was calibrated using the data for a 30-year period (1961–1990) and subsequently validated with the data for a 15-year period (1991–2005). Upon perceiving a satisfactory performance, the SDSM was then used for projecting the predictand variables (PREC, \(T_{\max}\) , and \(T_{\min}\) ) for the 21st century considering three representative concentration pathway (RCP) scenarios viz. RCP2.6, RCP4.5, and RCP8.5. The future period was divided into three 30-year time slices named epoch-1 (2011–2040), epoch-2 (2041–2070), and epoch-3 (2071–2100), respectively. The period 1976–2005 was considered as baseline period and all the future results were compared with this data. The results were analysed at various temporal scales, i.e., monthly, seasonal, and annual. The study has reveals that the KRB is going to become wetter during all the seasons. The results are discussed for the worst-case scenario, i.e., RCP8.5 epoch-3. The average annual maximum and minimum temperature is expected to increase. The extreme event analysis is also carried out considering the 90th and 95th percentile values. It is noticed that the extreme (90th and 95th percentiles) are going to increase. There are extreme events that go beyond extreme values. The outcome of this study can be used in flood modeling for the KRB and also for the modeling of future irrigation demands along with the planning of optimal irrigation in the KRB culturable area.

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气候变化对降水和气温的影响评估：印度克里希纳河流域案例研究

摘要本研究采用统计降尺度模式（SDSM）对克里希纳河流域（KRB）的降水量（PREC）、最高气温（T_{\max}\）和最低气温（T_{\min}\）进行降尺度。加拿大地球系统模式第 2 版（CanESM2）的大气环流模式（GCM）输出结果被视为预测变量。首先，利用 30 年（1961-1990 年）的数据对 SDSM 进行了校准，随后利用 15 年（1991-2005 年）的数据对其进行了验证。性能令人满意后，SDSM 被用于预测 21 世纪的预测变量（PREC、\(T_{\max}\) 和\(T_{\min}\) ），并考虑了三种代表性浓度路径（RCP）情景，即 RCP2.6、RCP4.5 和 RCP8.5。未来时期被划分为三个 30 年的时间片，分别称为 epoch-1（2011-2040 年）、epoch-2（2041-2070 年）和 epoch-3（2071-2100 年）。1976-2005 年期间被视为基线期，所有未来结果都与这一数据进行比较。对结果进行了不同时间尺度的分析，即月度、季节和年度。研究结果表明，KRB 在所有季节都将变得更加潮湿。研究结果针对最坏情况，即 RCP8.5 epoch-3 进行了讨论。预计年平均最高气温和最低气温都将上升。此外，还考虑了第 90 和第 95 百分位值，对极端事件进行了分析。我们注意到，极端事件（第 90 和第 95 百分位数）将会增加。有些极端事件超出了极值。本研究的结果可用于 KRB 的洪水建模，也可用于未来灌溉需求建模以及 KRB 可养殖区的最佳灌溉规划。

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来源期刊

Russian Meteorology and Hydrology METEOROLOGY & ATMOSPHERIC SCIENCES-

CiteScore

1.70

自引率

28.60%

发文量

审稿时长

4-8 weeks

期刊介绍： Russian Meteorology and Hydrology is a peer reviewed journal that covers topical issues of hydrometeorological science and practice: methods of forecasting weather and hydrological phenomena, climate monitoring issues, environmental pollution, space hydrometeorology, agrometeorology.