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使用生命周期评估法对不同水稻种植系统的碳足迹和温室气体排放情况

Carbon footprint and greenhouse gas emissions of different rice-based cropping systems using LCA.

作者信息

Jahangir Mohammad Mofizur Rahman, Aguilera Eduardo, Ferdous Jannatul, Mahjabin Farah, Al Asif Abdullah, Hossan Moutakin, Ahmad Hassan, Bauer Maximilian, Cobeña Alberto Sanz, Müller Christoph, Zaman Mohammad

机构信息

Department of Soil Science, Bangladesh Agricultural University, Mymensingh, 2202, Bangladesh.

Liebig Centre for Agroecology and Climate Impact Research, Justus Liebig University, Giessen, Germany.

出版信息

Sci Rep. 2025 Mar 25;15(1):10214. doi: 10.1038/s41598-025-90157-2.

DOI:10.1038/s41598-025-90157-2
PMID:40133385
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11937248/
Abstract

There are many cropping systems on floodplain soils, but greenhouse gas (GHG) emission balances of these agricultural systems are rarely reported. Carbon (C) footprints of agricultural products were assessed using a co-designed life cycle assessment tool in major cropping systems in Bangladesh: rice-rice-rice (R-R-R/boro-aus-aman), rice-fallow-rice (R-F-R/boro-fallow-aman), maize-fallow-rice (M-F-R), wheat-mungbean-rice (W-Mu-R), and potato-rice-fallow (P-R-F) along with the field measurement of some of the systems. The rice system with dryland crops had higher nitrous oxide (NO) emissions (3.8 in maize, 4.5 in potato and 0.92 kg NO-N ha in mungbean) than sole rice (0.73 in boro, 0.57 in aus and 1.94 kg NO-N ha in aman) systems but methane (CH) emissions exhibited the opposite. Methane dominated, accounting for 50-80% of total emissions in rice systems. The boro rice-based systems (R-R-R and R-F-R) had the highest C footprint (ca. 25.8 and 19.2 Mg COe ha) while the P-F-R (12.3 Mg COe ha) and M-F-R (12.6 Mg COe ha) had the lowest C footprint. Boro and aus were more suitable to reduce C footprint. Measured CH and NO data agreed well with the IPCC Tier 1 estimates but further study on GHG measurements in other agroecosystems and cropping systems are required to validate the estimation for adopting suitable GHG mitigation strategies.

摘要

洪泛区土壤上有多种种植系统,但这些农业系统的温室气体(GHG)排放平衡鲜有报道。利用共同设计的生命周期评估工具,对孟加拉国主要种植系统中农产品的碳(C)足迹进行了评估:稻-稻-稻(R-R-R/boro-aus-aman)、稻-休耕-稻(R-F-R/boro-休耕-aman)、玉米-休耕-稻(M-F-R)、小麦-绿豆-稻(W-Mu-R)和马铃薯-稻-休耕(P-R-F),并对其中一些系统进行了实地测量。与单季稻(boro为0.73,aus为0.57,aman为1.94千克一氧化二氮-N/公顷)系统相比,种植旱地作物的稻作系统一氧化二氮(NO)排放量更高(玉米为3.8,马铃薯为4.5,绿豆为0.92千克一氧化二氮-N/公顷),但甲烷(CH)排放量则相反。甲烷占主导,在稻作系统中占总排放量的50-80%。以boro稻为基础的系统(R-R-R和R-F-R)的碳足迹最高(约25.8和19.2 Mg CO₂e/公顷),而P-F-R(12.3 Mg CO₂e/公顷)和M-F-R(12.6 Mg CO₂e/公顷)的碳足迹最低。boro和aus更适合减少碳足迹。实测的CH和NO数据与IPCC一级估算结果吻合良好,但需要对其他农业生态系统和种植系统中的温室气体测量进行进一步研究,以验证估算结果,从而采用合适的温室气体减排策略。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7f91/11937248/e933843dc2a1/41598_2025_90157_Fig7_HTML.jpg
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