Advanced growing-season precipitation peak promotes soil nitrogen mineralization in a semi-arid grassland

IF 5.4 1区 农林科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY
Jiayin Feng , Xiaojing Yue , Benqing Li , Jingyi Ru , Zhenxing Zhou , Lingjie Kong , Jiajun Zhang , Jiaxin Zhou , Guilin Zhou , Wenjing Ma , Yaru Lyu , Jian Song , Shiqiang Wan
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Abstract

Soil nitrogen (N) mineralization is a key process of global N cycling and profoundly regulates plant productivity and soil nutrient pools in the terrestrial biosphere. However, its response to seasonal precipitation redistribution remains largely unexplored. As part of a nine-year (2013–2021) field experiment that simulated advanced and/or delayed growing-season precipitation peaks in a semi-arid grassland on the Mongolian Plateau, this study was conducted for two years (2020–2021) in situ to examine the effects of changing precipitation distributions in the growing seasons on soil mineralization processes. The results showed that advanced precipitation peak (AP) increased soil ammonification (Ramm), nitrification (Rnit), and net mineralization rates (Rmin) by 45.8 %, 26.0 %, and 84.4 %, respectively (all p < 0.001), whereas delayed precipitation peak (DP) enhanced Ramm by 55.7 % (p < 0.001) only, but did not change Rnit or Rmin. The elevated soil N mineralization under the AP treatment could be primarily attributed to the increased soil water availability and microbial biomass N in the early growing season, both of which play essential roles in meditating biological processes in the soil. In addition, the large consumption of soil inorganic N in the early and middle growing seasons may lead to an enhancement of ammonification in September. These observations suggest that advanced rather than delayed growing-season precipitation peak has a stronger influence on soil N dynamics in the growing seasons. Moreover, our findings highlight the positive contributions of altered N transformations to soil respiration and net ecosystem productivity under the AP treatment and imply the crucial roles of intra-annual redistribution of precipitation in regulating ecosystem nutrient and carbon cycling in semi-arid regions.
生长季降水峰值提前促进半干旱草原的土壤氮矿化
土壤氮(N)矿化是全球氮循环的一个关键过程,对陆地生物圈中的植物生产力和土壤养分库有着深远的影响。然而,其对季节性降水再分配的响应在很大程度上仍未得到探索。作为为期九年(2013-2021 年)模拟蒙古高原半干旱草原生长季降水峰值提前和/或延迟的野外实验的一部分,本研究在原地进行了两年(2020-2021 年),以考察生长季降水分布变化对土壤矿化过程的影响。结果表明,降水峰值提前(AP)使土壤氨化率(Ramm)、硝化率(Rnit)和净矿化率(Rmin)分别提高了45.8%、26.0%和84.4%(p均为0.001),而降水峰值延迟(DP)仅使Ramm提高了55.7%(p为0.001),但未改变Rnit和Rmin。AP 处理下土壤氮矿化度提高的主要原因可能是生长季初期土壤水分供应量和微生物生物量氮的增加,这两者在调解土壤生物过程中都起着至关重要的作用。此外,生长季初期和中期土壤无机氮的大量消耗可能会导致 9 月份氨化作用的增强。这些观察结果表明,生长季降水峰值的提前而非延迟对生长季的土壤氮动态影响更大。此外,我们的研究结果强调了在 AP 处理下,氮转化的改变对土壤呼吸和生态系统净生产力的积极贡献,并暗示了降水的年内再分配在调节半干旱地区生态系统养分和碳循环中的关键作用。
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
Catena
Catena 环境科学-地球科学综合
CiteScore
10.50
自引率
9.70%
发文量
816
审稿时长
54 days
期刊介绍: Catena publishes papers describing original field and laboratory investigations and reviews on geoecology and landscape evolution with emphasis on interdisciplinary aspects of soil science, hydrology and geomorphology. It aims to disseminate new knowledge and foster better understanding of the physical environment, of evolutionary sequences that have resulted in past and current landscapes, and of the natural processes that are likely to determine the fate of our terrestrial environment. Papers within any one of the above topics are welcome provided they are of sufficiently wide interest and relevance.
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