Understanding the transgression of global and regional freshwater planetary boundaries

Philosophical transactions. Series A, Mathematical, physical, and engineering sciences Pub Date : 2022-10-24 DOI:10.1098/rsta.2021.0294

A. Pastor, H. Biemans, W. Franssen, D. Gerten, H. Hoff, F. Ludwig, P. Kabat

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引用次数: 4

Abstract

Freshwater ecosystems have been degraded due to intensive freshwater abstraction. Therefore, environmental flow requirements (EFRs) methods have been proposed to maintain healthy rivers and/or restore river flows. In this study, we used the Variable Monthly Flow (VMF) method to calculate the transgression of freshwater planetary boundaries: (1) natural deficits in which flow does not meet EFRs due to climate variability, and (2) anthropogenic deficits caused by water abstractions. The novelty is that we calculated spatially and cumulative monthly water deficits by river types including the frequency, magnitude and causes of environmental flow (EF) deficits (climatic and/or anthropogenic). Water deficit was found to be a regional rather than a global concern (less than 5% of total discharge). The results show that, from 1960 to 2000, perennial rivers with low flow alteration, such as the Amazon, had an EF deficit of 2–12% of the total discharge, and that the climate deficit was responsible for up to 75% of the total deficit. In rivers with high seasonality and high water abstractions such as the Indus, the total deficit represents up to 130% of its total discharge, 85% of which is due to withdrawals. We highlight the need to allocate water to humans and ecosystems sustainably. This article is part of the Royal Society Science+ meeting issue ‘Drought risk in the Anthropocene’.

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了解全球和区域淡水行星边界的海侵

由于大量抽取淡水，淡水生态系统已经退化。因此，人们提出了环境流量要求(EFRs)方法来维持健康的河流和/或恢复河流流量。在本研究中，我们使用变月流量(VMF)方法来计算淡水地球边界的越界:(1)由于气候变率导致的自然赤字，即流量不满足efr;(2)由于水的抽取引起的人为赤字。新颖之处在于，我们按河流类型计算了空间和累计月水亏缺，包括环境流量(EF)亏缺的频率、幅度和原因(气候和/或人为)。水资源短缺是一个区域性问题，而不是全球性问题(不足总排放量的5%)。结果表明:1960 ~ 2000年，亚马逊河等流量变化较小的多年生河流的EF亏损量占总流量的2 ~ 12%，其中气候亏损量占总亏损量的75%。在具有高季节性和高抽水量的河流中，如印度河，总赤字占其总流量的130%，其中85%是由于提取。我们强调需要可持续地为人类和生态系统分配水资源。这篇文章是皇家学会科学+会议议题“人类世的干旱风险”的一部分。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Philosophical transactions. Series A, Mathematical, physical, and engineering sciences

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