More than three-fold increase in compound soil and air dryness across Europe by the end of 21st century

IF 5.3 2区 材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY ACS Applied Nano Materials Pub Date : 2024-03-28 DOI:10.1016/j.wace.2024.100666
Ankit Shekhar , Nina Buchmann , Vincent Humphrey , Mana Gharun
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Abstract

Increases in air temperature lead to increased dryness of the air and potentially develops increased dryness in the soil. Extreme dryness (in the soil and/or in the atmosphere) affects the capacity of ecosystems for functioning and for modulating the climate. Here, we used long-term high temporal resolution (daily) soil moisture (SM) and vapor pressure deficit (VPD) data of high spatial resolution (∼0.1° × 0.1°) to show that compared to the reference period (1950–1990), the overall frequency of extreme soil dryness, extreme air dryness, and extreme compound dryness (i.e., co-occurrence of extreme soil dryness and air dryness) has increased by 1.2-fold [0.8,1.6] (median [10th,90th percentile], 1.6-fold [1,2.3], and 1.7-fold [0.9,2.5], respectively, over the last 31 years (1991–2021) across Europe. Our results also indicate that this increase in frequency of extreme compound dryness (between reference and 1991–2021 period) is largely due to increased SM-VPD coupling across Northern Europe, and due to decreasing SM and/or increasing VPD trend across Central and Mediterranean Europe. Furthermore, under the RCP8.5 (Representative Concentration Pathways 8.5) emission scenario, this increase in frequency of extreme compound dryness would be 3.3-fold [2.0,5.8], and 4.6-fold [2.3,11.9] by mid-21st century (2031–2065) and late-21st century (2066–2100), respectively. Additionally, we segregated the changes in frequency of extreme dryness across the most recent (year 2021) land cover types in Europe to show that croplands, broadleaved forest, and urban areas have experienced more than twice as much extreme dryness during 1990–2021 compared to the reference period of 1990–2021, which based on the future projection data will increase to more than three-fold by mid 21st century. Such future climate-change induced increase in extreme dryness could have negative implications for functioning of ecosystems and compromise their capacity to adapt to rapidly rising dryness levels.

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到 21 世纪末,整个欧洲的复合土壤和空气干燥度将增加三倍以上
气温升高导致空气更加干燥,并可能导致土壤更加干燥。极端干燥(土壤和/或大气)会影响生态系统的功能和调节气候的能力。在这里,我们利用高空间分辨率(∼0.1° × 0.1°)的长期高时间分辨率(日)土壤水分(SM)和水汽压差(VPD)数据表明,与参照期(1950-1990 年)相比,极端土壤干燥、极端空气干燥和极端复合干燥(即:极端土壤干燥、极端空气干燥和极端复合干燥)的总体频率增加了、在过去 31 年(1991-2021 年)中,整个欧洲的极端土壤干燥、极端空气干燥和极端复合干燥(即极端土壤干燥和极端空气干燥同时出现)的总体频率分别增加了 1.2 倍 [0.8,1.6](中位数 [第 10 和第 90 百分位数],1.6 倍 [1,2.3] 和 1.7 倍 [0.9,2.5])。我们的研究结果还表明,极端复合干旱频率的增加(参考值与1991-2021年期间)主要是由于北欧SM-VPD耦合的增加,以及中欧和地中海地区SM减少和/或VPD增加的趋势。此外,在 RCP8.5(代表性气候路径 8.5)排放情景下,到 21 世纪中期(2031-2065 年)和 21 世纪晚期(2066-2100 年),极端复合干旱频率将分别增加 3.3 倍[2.0,5.8]和 4.6 倍[2.3,11.9]。此外,我们还对欧洲最近(2021 年)土地覆被类型的极端干旱频率变化进行了分类,结果表明,与 1990-2021 年参照期相比,1990-2021 年期间耕地、阔叶林和城市地区的极端干旱频率增加了两倍多,而根据未来预测数据,到 21 世纪中叶,极端干旱频率将增加三倍多。未来气候变化引起的这种极端干旱的增加可能会对生态系统的功能产生负面影响,并损害其适应快速上升的干旱水平的能力。
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来源期刊
CiteScore
8.30
自引率
3.40%
发文量
1601
期刊介绍: ACS Applied Nano Materials is an interdisciplinary journal publishing original research covering all aspects of engineering, chemistry, physics and biology relevant to applications of nanomaterials. The journal is devoted to reports of new and original experimental and theoretical research of an applied nature that integrate knowledge in the areas of materials, engineering, physics, bioscience, and chemistry into important applications of nanomaterials.
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