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农田生态系统碳源与碳汇的研究现状及未来趋势:文献计量分析(2002 - 2023年)

Current Progress and Future Trends in Carbon Sources and Sinks in Farmland Ecosystems: A Bibliometric Analysis (2002-2023).

作者信息

Pang Yugong, Zhang Menghao, Zhong Hesen, Cevin Tibihenda, Sun Chuanzhun, Zhang Shoutao, Li Xinyu, Dai Jun, Liu Chengshuai, Zhang Chi

机构信息

College of Natural Resources and Environment, South China Agricultural University, Guangzhou 510642, China.

Tanzania Agricultural Research Institute, Dodoma 1571, Tanzania.

出版信息

Biology (Basel). 2025 Apr 2;14(4):365. doi: 10.3390/biology14040365.

DOI:10.3390/biology14040365
PMID:40282230
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12024742/
Abstract

Farmland ecosystems, as the most active carbon pool, are integral to global climate change and carbon cycling. Therefore, systematically studying the roles of carbon sources and sinks in farmland ecosystems is essential to deepening our understanding of the carbon cycle and meeting the goals of "peak carbon emissions" and "carbon neutrality" in agriculture. Using the Web of Science database, this study reviewed 1411 articles (2002-2023) via bibliometric analysis to identify key research themes, trends, future priorities and address suggestions for future directions in farmland ecosystem carbon sources and sinks. The main results include the following: (1) Over the past 22 years, global research in this field has shown a consistent growth trend, with remarkably rapid expansion in the past three years. China, the United States, and Germany are the most influential countries. As the research scope has expanded, the field has evolved into an interdisciplinary domain. (2) The diversity of this research area has become enriched, and the research content is becoming more refined and systematic. The main research topics focus on carbon sequestration, soil organic carbon (SOC), farmland management, greenhouse gas (GHG) emissions, carbon stocks, ecosystem services, land use changes, climate change, and spatiotemporal heterogeneity. (3) Current research hotspots primarily focus on studying soil microbial carbon sequestration mechanisms, the application of remote sensing technologies, and reducing GHG emissions to achieve "carbon neutrality". While existing studies have systematically elucidated carbon sequestration mechanisms mediated by soil aggregates, microorganisms, and minerals, critical knowledge gaps persist. Regional disparities in the relative contributions of these mechanisms remain unresolved, compounded by methodological inconsistencies in carbon assessment that introduce substantial uncertainties. Although farmland management practices are identified as pivotal drivers of carbon flux variation, the interactive effects of anthropogenic interventions and natural factors on ecosystem-scale carbon balance require further mechanistic exploration. This review provides a comprehensive reference for further study on carbon sources and sinks of farmland ecosystems and devising effective emission reduction strategies.

摘要

农田生态系统作为最活跃的碳库,对全球气候变化和碳循环至关重要。因此,系统研究农田生态系统中碳源和碳汇的作用,对于深化我们对碳循环的理解以及实现农业“碳排放达峰”和“碳中和”目标至关重要。本研究利用科学网数据库,通过文献计量分析对1411篇文章(2002 - 2023年)进行了综述,以确定农田生态系统碳源和碳汇的关键研究主题、趋势、未来重点以及对未来方向的应对建议。主要结果如下:(1)在过去22年中,该领域的全球研究呈现出持续增长的趋势,在过去三年中显著快速扩张。中国、美国和德国是最具影响力的国家。随着研究范围的扩大,该领域已发展成为一个跨学科领域。(2)该研究领域的多样性变得更加丰富,研究内容也越来越精细和系统。主要研究主题集中在碳固存、土壤有机碳、农田管理、温室气体排放、碳储量、生态系统服务、土地利用变化、气候变化以及时空异质性。(3)当前的研究热点主要集中在研究土壤微生物碳固存机制、遥感技术的应用以及减少温室气体排放以实现“碳中和”。虽然现有研究已经系统地阐明了由土壤团聚体、微生物和矿物质介导的碳固存机制,但关键的知识空白仍然存在。这些机制的相对贡献在区域上的差异仍未得到解决,再加上碳评估方法的不一致,带来了大量的不确定性。尽管农田管理实践被认为是碳通量变化的关键驱动因素,但人为干预和自然因素对生态系统尺度碳平衡的交互作用仍需要进一步的机理探索。本综述为进一步研究农田生态系统的碳源和碳汇以及制定有效的减排策略提供了全面的参考。

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本文引用的文献

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