Climate change rivals fertilizer use in driving soil nitrous oxide emissions in the northern high latitudes: Insights from terrestrial biosphere models

IF 10.3 1区环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES Environment International Pub Date : 2025-02-01 DOI:10.1016/j.envint.2025.109297

Naiqing Pan , Hanqin Tian , Hao Shi , Shufen Pan , Josep G. Canadell , Jinfeng Chang , Philippe Ciais , Eric A. Davidson , Gustaf Hugelius , Akihiko Ito , Robert B. Jackson , Fortunat Joos , Sebastian Lienert , Dylan B. Millet , Stefan Olin , Prabir K. Patra , Rona L. Thompson , Nicolas Vuichard , Kelley C. Wells , Chris Wilson , Sönke Zaehle

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Abstract

Nitrous oxide (N₂O) is the most important stratospheric ozone-depleting agent based on current emissions and the third largest contributor to increased net radiative forcing. Increases in atmospheric N₂O have been attributed primarily to enhanced soil N₂O emissions. Critically, contributions from soils in the Northern High Latitudes (NHL, >50°N) remain poorly quantified despite their exposure to rapid rates of regional warming and changing hydrology due to climate change. In this study, we used an ensemble of six process-based terrestrial biosphere models (TBMs) from the Global Nitrogen/Nitrous Oxide Model Intercomparison Project (NMIP) to quantify soil N₂O emissions across the NHL during 1861–2016. Factorial simulations were conducted to disentangle the contributions of key driving factors, including climate change, nitrogen inputs, land use change, and rising atmospheric CO₂ concentration, to the trends in emissions. The NMIP models suggests NHL soil N₂O emissions doubled from 1861 to 2016, increasing on average by 2.0 ± 1.0 Gg N/yr (p < 0.01). Over the entire study period, while N fertilizer application (42 ± 20 %) contributed the largest share to the increase in NHL soil emissions, climate change effect was comparable (37 ± 25 %), underscoring its significant role. In the recent decade (2007–2016), anthropogenic sources contributed 47 ± 17 % (279 ± 156 Gg N/yr) of the total N₂O emissions from the NHL, while unmanaged soils contributed a comparable amount (290 ± 142 Gg N/yr). The trend of increasing emissions from nitrogen fertilizer reversed after the 1980 s because of reduced applications in non-permafrost regions. In addition, increased plant growth due to CO₂ fertilization suppressed simulated emissions. However, permafrost soil N₂O emissions continued increasing attributable to climate warming; the interaction of climate warming and increasing CO₂ concentrations on nitrogen and carbon cycling will determine future trends in NHL soil N₂O emissions. The rigorous interplay between process modeling and field experimentation will be essential for improving model representations of the mechanisms controlling N₂O fluxes in the Northern High Latitudes and for reducing associated uncertainties.

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陆地生物圈模式集合估算的北部高纬度地区土壤一氧化二氮排放

根据目前的排放，氧化亚氮（N2O）是最重要的平流层臭氧消耗剂，也是净辐射强迫增加的第三大因素。大气中N2O的增加主要归因于土壤N2O排放的增加。至关重要的是，北高纬度地区（NHL, >50°N）土壤的贡献仍然难以量化，尽管它们受到气候变化导致的区域变暖和水文变化的快速影响。在这项研究中，我们使用了来自全球氮/氧化亚氮模式比对项目（NMIP）的六个基于过程的陆地生物圈模型（tbm），对1861-2016年NHL的土壤N2 O排放进行了量化。因子模拟分析了气候变化、氮输入、土地利用变化和大气CO2浓度上升等关键驱动因子对排放趋势的影响。NMIP模型显示，从1861年到2016年，NHL土壤N2O排放量增加了一倍，平均增加2.0 ± 1.0 Gg N/yr （p <； 0.01）。在整个研究期内，氮肥施用对NHL土壤排放增加的贡献最大（42 ± 20 %），其次是气候变化（37 ± 25 %）。近十年（2007-2016年），人为源贡献了NHL N2O总排放量的47 ± 17 %(279 ± 156 Gg N/yr)，而未经管理的土壤贡献了相当数量的N2O（290 ± 142 Gg N/yr）。20世纪80年代 以后，由于在非永久冻土区的施用减少，氮肥排放量增加的趋势发生了逆转。此外，由于CO2施肥导致的植物生长增加抑制了模拟排放。然而，由于气候变暖，多年冻土土壤N2O排放量持续增加；气候变暖和CO2浓度增加对氮和碳循环的相互作用将决定NHL土壤N2O排放的未来趋势。过程模拟和现场实验之间的严格相互作用对于改进控制北部高纬度地区N2O通量机制的模式表示和减少相关的不确定性至关重要。

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

Environment International 环境科学-环境科学

CiteScore

21.90

自引率

3.40%

发文量

734

审稿时长

2.8 months

期刊介绍： Environmental Health publishes manuscripts focusing on critical aspects of environmental and occupational medicine, including studies in toxicology and epidemiology, to illuminate the human health implications of exposure to environmental hazards. The journal adopts an open-access model and practices open peer review. It caters to scientists and practitioners across all environmental science domains, directly or indirectly impacting human health and well-being. With a commitment to enhancing the prevention of environmentally-related health risks, Environmental Health serves as a public health journal for the community and scientists engaged in matters of public health significance concerning the environment.