U.S. Geological Survey, Princeton, NJ, USA.
Science. 2020 Mar 13;367(6483):1252-1255. doi: 10.1126/science.aay9187. Epub 2020 Feb 20.
The sensitivity of river discharge to climate-system warming is highly uncertain, and the processes that govern river discharge are poorly understood, which impedes climate-change adaptation. A prominent exemplar is the Colorado River, where meteorological drought and warming are shrinking a water resource that supports more than 1 trillion dollars of economic activity per year. A Monte Carlo simulation with a radiation-aware hydrologic model resolves the longstanding, wide disparity in sensitivity estimates and reveals the controlling physical processes. We estimate that annual mean discharge has been decreasing by 9.3% per degree Celsius of warming because of increased evapotranspiration, mainly driven by snow loss and a consequent decrease in reflection of solar radiation. Projected precipitation increases likely will not suffice to fully counter the robust, thermodynamically induced drying. Thus, an increasing risk of severe water shortages is expected.
河流径流量对气候系统变暖的敏感性高度不确定,而且控制河流径流量的过程还不甚了解,这阻碍了气候变化适应工作的开展。科罗拉多河就是一个突出的例子,那里的气象干旱和变暖正在缩减一项每年支持超过 1 万亿美元经济活动的水资源。一个带有辐射感知水文模型的蒙特卡罗模拟解决了长期以来对敏感性估计存在的巨大差异,并揭示了控制物理过程。我们估计,由于蒸散量增加,主要是由于积雪损失和太阳辐射反射减少,每年平均径流量每升温 1 摄氏度就减少 9.3%。预计增加的降水量可能不足以完全抵消这种强大的、由热力学引起的干燥。因此,预计严重水资源短缺的风险将会增加。
