农作物的反照率是应对全球变暖的自然气候解决方案

Cheyenne Lei, Jiquan Chen, Ines Ibanez, P. Sciusco, Gabriela Shirkey, Ming Lei, Peter Reich, G. P. Robertson
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摘要

地表反照率会影响能量预算,进而导致局部气候变暖或变冷。当我们将大部分土地转为农业用地时,地表属性会随之改变,包括反照率。通过作物选择和管理,人们可以增加作物的反照率,从而获得更高水平的局部降温效应,缓解全球变暖。然而,对于种植系统的独特特征如何导致反照率升高,进而提高耕地的降温潜力,人们还知之甚少。为了解决这个紧迫的问题,我们在五个生长季期间对三种农艺强度的玉米-大豆-冬小麦(Zea mays L.- Glycine max L. Merrill - Triticum aestivum L.;CSW)轮作一年生作物、多年生开关草(Panicum virgatum L.)单一作物以及早期演替草原和恢复草原的多年生多茬作物的地表反射率进行了季节性测量。我们发现,作物种类、农艺强度、季节性和植物物候对反照率有显著影响。反照率的平均值(±SD)在多年生开关草作物中最高(0.179±0.04),在早期演替作物中居中(0.170±0.04),而在减少投入的覆盖作物玉米系统中最低(0.154±0.02)。大豆(-0.450 kg CO2e m-2 yr-1)和开关草(-0.367 kg CO2e m-2 yr-1)的降温潜力最强,不同农业生态系统每年提供的局部气候降温可达-0.265 kg CO2e m-2 yr-1。我们还展示了不同的生态系统、叶冠和农艺实践如何影响地表反射率,并为在局部范围内减少全球变暖提供了另一种潜在的基于自然的解决方案。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Albedo of crops as a nature-based climate solution to global warming
Surface albedo can affect the energy budget and subsequently cause localized warming or cooling of the climate. When we convert a substantial portion of lands to agriculture, land surface properties are consequently altered, including albedo. Through crop selection and management, one can increase crop albedo to obtain higher levels of localized cooling effects to mitigate global warming. Still, there is little understanding about how distinctive features of a cropping system may be responsible for elevated albedo and consequently for the cooling potential of cultivated lands. To address this pressing issue, we conducted seasonal measurements of surface reflectivity during five growing seasons on annual crops of corn-soybean–winter wheat (Zea mays L.- Glycine max L. Merrill - Triticum aestivum L.; CSW) rotations at three agronomic intensities, a monoculture of perennial switchgrass (Panicum virgatum L.), and perennial polycultures of early successional and restored prairie grasslands. We found that crop-species, agronomic intensity, seasonality, and plant phenology had significant effects on albedo. The mean±SD albedo was highest in perennial crops of switchgrass (0.179±0.04), intermediate in early successional crops (0.170±0.04), and lowest in a reduced input corn systems with cover crops (0.154±0.02). The strongest cooling potentials were found in soybean (-0.450 kg CO2e m-2 yr-1) and switchgrass (-0.367 kg CO2e m-2 yr-1), with up to -0.265 kg CO2e m-2 yr-1 of localized climate cooling annually provided by different agroecosystems. We also demonstrated how diverse ecosystems, leaf canopy, and agronomic practices can affect surface reflectivity and provide another potential nature-based solution for reducing global warming at localized scales.
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