环境科学
温室气体
一氧化二氮
全球变暖
土壤水分
生态系统
大气科学
温带气候
氮气循环
气候变化
水分
温带森林
碳循环
氮气
降水
陆地生态系统
含水量
森林生态学
土壤碳
气候模式
温带雨林
营养物
生产力
初级生产
水循环
生物地球化学
固碳
土壤科学
农学
全球变化
温室效应
水文学(农业)
温带落叶林
营养循环
二氧化碳
作者
Kai Huang,Di Wu,Dongwei Liu,Yihang Duan,Peter Dörsch,Klaus Butterbach‐Bahl,Xiao-Ming Fang,Yuqi Liu,Chao Wang,Haoming Yu,Lingrui Qu,Junjie Xu,Geshere Abdisa Gurmesa,Ronghua Kang,Shushi Peng,Erik A. Hobbie,Xiaotang Ju,Shuijin Hu,Oliver L. Phillips,Per Gundersen
标识
DOI:10.1073/pnas.2513401122
摘要
Global warming is projected to accelerate ecosystem nitrogen (N) loss via gaseous pathways, thereby decreasing N availability, a critical nutrient for primary productivity and carbon sequestration. However, the models forecasting this ecosystem N loss are based on laboratory experiments that are inherently uncertain and have had few in situ validations. Over 6 y, we measured ~200,000 soil nitric oxide (NO; an air pollutant) and nitrous oxide (N 2 O; a powerful greenhouse gas) fluxes and used an upscaling approach to estimate N 2 fluxes after warming a temperate forest by 2 °C. Against thermodynamic theoretical predictions, warming unequivocally lowered emissions of NO by 19% and of N 2 O by 16%. These lower gaseous N losses were not explained by complete reduction of NO and N 2 O to N 2 , leaching, nor plant uptake, but rather by the warming-induced drying of soils that constrained microbial activity, consistent with other warming experiments where precipitation was less than 1,000 mm y −1 . Our findings challenge ecosystem model assumptions where warming, alone, accelerates N emissions and underscores how warming-induced losses in soil moisture and shortened freeze-thaw periods can offset temperature effects. Our data underscore the need for explicit consideration of in situ soil moisture when predicting changes on the terrestrial N cycle as the planet warms.
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