Exploring potential trade-offs in outdoor water use reductions and urban tree ecosystem services during an extreme drought in Southern California

IF 3.3 Q2 ENVIRONMENTAL SCIENCES
Rachel Torres, C. Tague, Joseph P. McFadden
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Abstract

In Southern California cities, urban trees play a vital role in alleviating heat waves through shade provision and evaporative cooling. Trees in arid to semi-arid regions may rely on irrigation, which is often the first municipal water use to be restricted during drought, causing further drought stress. Finding a balance between efficient water use and maintaining tree health will be crucial for long-term urban forestry and water resources management, as climate change will increase drought and extreme heat events. This study aimed to quantify how urban tree water and carbon fluxes are affected by irrigation reductions, and how that relationship changes with tree species and temperature. We used an ecohydrologic model that mechanistically simulates water, carbon, and energy cycling, parameterized for 5 common tree species in a semi-arid urban area. We simulated a range of irrigation reductions based on average outdoor water use data from the city for a recent extreme drought as well as with warmer temperatures. We then analyzed the response of model outcomes of plant carbon fluxes, leaf area index (LAI), and water use. Results show that reducing irrigation up to 25%, a comparable amount as the California state mandate in 2014, has minimal effects on tree primary productivity and water use efficiency. We found that transpiration was linearly related to irrigation input, which could lead to a short-term loss of evaporative cooling with irrigation reductions during drought. However, primary productivity and LAI had a nonlinear response to irrigation, indicating shade provision could be maintained throughout drought with partial irrigation reductions. Results varied across tree species, with some species showing greater sensitivity of productivity to both irrigation reductions and potentially warmer droughts. These results have implications for water resources management before and during drought, and for urban tree climate adaptation to future drought.
探索南加州特大干旱期间减少室外用水量与城市树木生态系统服务之间的潜在权衡关系
在南加州城市,城市树木通过遮荫和蒸发冷却在缓解热浪方面发挥着重要作用。干旱和半干旱地区的树木可能依赖灌溉,而灌溉往往是干旱期间首先受到限制的市政用水,从而造成进一步的干旱压力。由于气候变化将加剧干旱和极端高温事件,因此在高效用水和保持树木健康之间找到平衡点对于长期的城市林业和水资源管理至关重要。本研究旨在量化城市树木的水和碳通量如何受到灌溉减少的影响,以及这种关系如何随着树木种类和温度的变化而变化。我们使用了一个生态水文模型,该模型从机理上模拟了水、碳和能量循环,并为半干旱城市地区的 5 种常见树种设定了参数。我们根据该市最近一次极端干旱和气温升高时的平均室外用水数据,模拟了一系列灌溉减少量。然后,我们分析了模型结果对植物碳通量、叶面积指数(LAI)和用水量的响应。结果表明,将灌溉量减少至 25%(与 2014 年加利福尼亚州规定的灌溉量相当)对树木初级生产力和用水效率的影响微乎其微。我们发现蒸腾作用与灌溉投入呈线性关系,这可能会导致干旱期间减少灌溉造成的短期蒸发冷却损失。然而,初级生产力和LAI对灌溉的反应是非线性的,这表明部分减少灌溉可以在整个干旱期间保持遮荫效果。不同树种的结果各不相同,有些树种的生产力对减少灌溉和可能变暖的干旱更为敏感。这些结果对干旱前和干旱期间的水资源管理,以及城市树木对未来干旱气候的适应具有重要意义。
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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来源期刊
Frontiers in Climate
Frontiers in Climate Environmental Science-Environmental Science (miscellaneous)
CiteScore
4.50
自引率
0.00%
发文量
233
审稿时长
15 weeks
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