脱碳过程中的氮管理

Xin Zhang, Robert Sabo, Lorenzo Rosa, Hassan Niazi, Page Kyle, Jun Suk Byun, Yanyu Wang, Xiaoyuan Yan, Baojing Gu, Eric A. Davidson
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摘要

去碳化对于应对气候变化至关重要。然而,一些脱碳战略可能会对氮循环产生深远影响。在本《综述》中,我们探讨了五大去碳化战略对氮的需求,以揭示碳循环和氮循环之间复杂的相互联系,并找出加强两者相互可持续管理的机会。一些脱碳战略需要大量新的氮生产,可能会导致营养污染加剧,加剧水生系统的富营养化。例如,用氨燃料替代海运中使用的 44% 化石燃料的策略可使二氧化碳排放量减少多达 0.38 千兆吨二氧化碳当量/年,但需要相应增加新的氮合成量 212 千兆吨氮/年。同样,使用生物燃料来实现 0.7 ± 0.3 Gt CO2-eq yr-1 的减排量,需要每年向农田投入 21-42 Tg N。为避免增加氮的损失和加剧富营养化,脱碳努力应旨在提供碳氮共同效益。减少碳密集型合成氮肥的使用就是一个例子,它可以同时减少每年 14 吨氮的输入和每年 0.04(0.03-0.06)亿吨二氧化碳当量的排放。未来的研究应指导脱碳工作,以缓解富营养化并提高农业、食品和能源系统的氮利用效率。
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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Nitrogen management during decarbonization
Decarbonization is crucial to combat climate change. However, some decarbonization strategies could profoundly impact the nitrogen cycle. In this Review, we explore the nitrogen requirements of five major decarbonization strategies to reveal the complex interconnections between the carbon and nitrogen cycles and identify opportunities to enhance their mutually sustainable management. Some decarbonization strategies require substantial new nitrogen production, potentially leading to increased nutrient pollution and exacerbation of eutrophication in aquatic systems. For example, the strategy of substituting 44% of fossil fuels used in marine shipping with ammonia-based fuels could reduce CO2 emissions by up to 0.38 Gt CO2-eq yr−1 but would require a corresponding increase in new nitrogen synthesis of 212 Tg N yr−1. Similarly, using biofuels to achieve 0.7 ± 0.3 Gt CO2-eq yr−1 mitigation would require new nitrogen inputs to croplands of 21–42 Tg N yr−1. To avoid increasing nitrogen losses and exacerbating eutrophication, decarbonization efforts should be designed to provide carbon–nitrogen co-benefits. Reducing the use of carbon-intensive synthetic nitrogen fertilizer is one example that can simultaneously reduce both nitrogen inputs by 14 Tg N yr−1 and CO2 emissions by 0.04 (0.03–0.06) Gt CO2-eq yr−1. Future research should guide decarbonization efforts to mitigate eutrophication and enhance nitrogen use efficiency in agriculture, food and energy systems. Decarbonization strategies can perturb the nitrogen cycle through elevating nitrogen inputs to the environment, potentially driving increased eutrophication. This Review explores the potential synergistic and antagonistic impacts on carbon and nitrogen emissions from five major decarbonization strategies.
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