Evaluating changes in flood frequency due to climate change in the Western Cape, South Africa

IF 3.9 3区环境科学与生态学 Q1 ENGINEERING, CIVIL

Stochastic Environmental Research and Risk Assessment Pub Date : 2024-07-30 DOI:10.1007/s00477-024-02786-0

Kamleshan Pillay, Mulala Danny Simatele

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Abstract

This study assesses the impact of climate change on flood frequency across seven sites in the Western Cape province of South Africa. The calibrated Water Resources Simulation Model (WRSM)/Pitman hydrological model was run using precipitation inputs from two representative concentration pathways (RCP) scenarios (RCP 4.5 and 8.5) using a combination of eight global circulatory models (GCM) for the two periods (2030–2060 and 2070–2100). GCMs were statistically downscaled using the delta change (DC), linear scaling (LS) and quantile delta mapping (QDM) approaches. Average daily discharge was estimated from each downscaled daily precipitation dataset using the Pitman/WRSM model with the Fuller and Sangal estimation methods used to calculate daily instantaneous peak flows. Flood frequency curves (FFC) were generated using the annual maximum series (AMS) for the GCM ensemble mean and individual GCMs for the return periods between 2 and 100 years. FFCs generated based on LS and QDM downscaling methods were aligned for the GCM ensemble mean in terms of the direction of FFCs. Further analysis was conducted using outputs based on the QDM approach, given its suitability in projecting peak flows. Under this method, both Fuller and Sangal FFCs exhibited a decreasing trend across the Jonkershoek and Little Berg River sites; however, estimated quantiles for low-probability events were higher under the Fuller method. This study noted the variation in FFCs from individual GCMs compared to the FFC representing the GCM ensemble mean. Further research on climate change flood frequency analysis (FFA) in South Africa should incorporate other advanced downscaling and instantaneous peak flow estimation (IPF) methods.

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评估南非西开普省因气候变化导致的洪水频率变化

本研究评估了气候变化对南非西开普省七个地点洪水频率的影响。在两个时期（2030-2060 年和 2070-2100 年），利用八个全球环流模型 (GCM) 组合，使用两种代表性浓度路径 (RCP) 情景（RCP 4.5 和 8.5）的降水输入，运行校准过的水资源模拟模型 (WRSM)/Pitman 水文模型。使用三角洲变化 (DC)、线性缩放 (LS) 和量化三角洲绘图 (QDM) 方法对全球环流模型进行了统计降尺度。使用 Pitman/WRSM 模型从每个降尺度日降水量数据集估算日平均排水量，并使用 Fuller 和 Sangal 估算方法计算日瞬时峰值流量。洪水频率曲线 (FFC) 是使用 GCM 集合平均值的年最大序列 (AMS) 以及 2 至 100 年回归期的单个 GCM 生成的。基于 LS 和 QDM 降尺度方法生成的 FFC 与 GCM 集合平均值的 FFC 方向一致。考虑到 QDM 方法适合预测峰值流量，我们使用该方法的输出结果进行了进一步分析。在此方法下，Fuller 和 Sangal FFCs 在 Jonkershoek 和 Little Berg 河站点都呈现出下降趋势；不过，在 Fuller 方法下，低概率事件的估计量位值较高。本研究注意到，与代表全球气候模型集合平均值的 FFC 相比，单个全球气候模型的 FFC 存在差异。对南非气候变化洪水频率分析 (FFA) 的进一步研究应纳入其他先进的降尺度和瞬时峰值流量估算 (IPF) 方法。

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来源期刊

Stochastic Environmental Research and Risk Assessment 环境科学-工程：环境

CiteScore

7.10

自引率

9.50%

发文量

189

审稿时长

3.8 months

期刊介绍： Stochastic Environmental Research and Risk Assessment (SERRA) will publish research papers, reviews and technical notes on stochastic and probabilistic approaches to environmental sciences and engineering, including interactions of earth and atmospheric environments with people and ecosystems. The basic idea is to bring together research papers on stochastic modelling in various fields of environmental sciences and to provide an interdisciplinary forum for the exchange of ideas, for communicating on issues that cut across disciplinary barriers, and for the dissemination of stochastic techniques used in different fields to the community of interested researchers. Original contributions will be considered dealing with modelling (theoretical and computational), measurements and instrumentation in one or more of the following topical areas: - Spatiotemporal analysis and mapping of natural processes. - Enviroinformatics. - Environmental risk assessment, reliability analysis and decision making. - Surface and subsurface hydrology and hydraulics. - Multiphase porous media domains and contaminant transport modelling. - Hazardous waste site characterization. - Stochastic turbulence and random hydrodynamic fields. - Chaotic and fractal systems. - Random waves and seafloor morphology. - Stochastic atmospheric and climate processes. - Air pollution and quality assessment research. - Modern geostatistics. - Mechanisms of pollutant formation, emission, exposure and absorption. - Physical, chemical and biological analysis of human exposure from single and multiple media and routes; control and protection. - Bioinformatics. - Probabilistic methods in ecology and population biology. - Epidemiological investigations. - Models using stochastic differential equations stochastic or partial differential equations. - Hazardous waste site characterization.