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Environmental Earth Sciences
Erschienen in: Environmental Earth Sciences 2/2024

01.01.2024 | Original Article

The impact of agricultural land use change on agricultural GHG emissions in China

verfasst von: Hu Yi, Jiang Penghui, Li Manchun

Erschienen in: Environmental Earth Sciences | Ausgabe 2/2024

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Abstract

The agricultural field is a major source of greenhouse gas (GHG) emissions. Therefore, we aimed to estimate agricultural GHG emissions to aid the reduction of GHG emissions from agricultural systems. We used the emission factor method, CLUMondo model to quantitatively calculate agricultural GHG emissions at the interprovincial and regional scales in China. Additionally, we qualitatively analysed the spatial distribution, carbon source structure, and gas types of agricultural GHG emissions at various stages. The results revealed that the spatial pattern of agricultural land in 2035 will generally be consistent with that in 2020 under the natural development scenario. Overall, agricultural GHG emissions will continue to increase. The simulation results showed that in east, south, southwest, and central China, the agricultural GHG emissions remained high, and gradually, the region in the southwest and northeast China emerged as an agglomeration of provinces with high agricultural GHG emissions. Notably, crop farming and animal husbandry acted as the primary source of agricultural GHG emissions in China. Overall, methane emissions increased marginally, nitrous oxide emissions increased substantially, and their proportion gradually approached 50%. Thus, to reduce the agricultural GHG emissions in China, the GHG emissions from crop farming and animal husbandry should be reduced. The target spatial pattern construction should be that of agricultural land with low GHG emissions.
Vorheriger Artikel Influence of biomass and chemicals on kinetics of ureolysis-based carbonate biomineral precipitation
Nächster Artikel Advanced modeling for flash flood susceptibility mapping using remote sensing and GIS techniques: a case study in Northeast Algeria

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Literatur
Amundson R, Berhe AA, Hopmans JW et al (2015) Soil and human security in the 21st century. Science 348(6235):1261071CrossRef
Bai Z, Ma L, Jin S et al (2016) Nitrogen, phosphorus, and potassium flows through the manure management chain in China. Environ Sci Technol 50(24):13409–13418CrossRef
Burney JA, Davis SJ, Lobell DB (2010) Greenhouse gas mitigation by agricultural intensification. Proc Natl Acad Sci USA 107:12052–12057CrossRef
Carlson KM, Gerber JS, Mueller ND et al (2017) Greenhouse gas emissions intensity of global croplands. Nat Clim Change 7:63–68CrossRef
Chen S, Gong B (2021) Response and adaptation of agriculture to climate change: evidence from China. J Dev Econ 148:102557CrossRef
Chen KX, Tao WH, Fang XL et al (2022a) Carbon neutrality assessment and planning application path in territorial spatial planning. Planners 38:134–141
Chen MP, Cui YR, Jiang S et al (2022b) Toward carbon neutrality before 2060: trajectory and technical mitigation potential of non-CO2 greenhouse gas emissions from Chinese agriculture. J Clean Prod 368:133186CrossRef
Clark MA, Domingo NGG, Colgan K et al (2020) Global food system emissions could preclude achieving the 1.5℃ and 2℃ climate change targets. Science 370(6517):705CrossRef
Cong XH, Shi FZ, Ruan XM et al (2019) Effects of nitrogen application rate on nitrogen use efficiency and key enzymes for carbon and nitrogen metabolism in different rice varieties. J Henan Agric Univ 53(03):325–330
Cui X, Zhou F, Ciais P et al (2021) Global mapping of crop-specific emission factors highlights hotspots of nitrous oxide mitigation. Nature Food 2:886–893CrossRef
Debonne N, van Vliet J, Heinimann A et al (2018) Representing large-scale land acquisitions in land use change scenarios for the Lao PDR. Reg Environ Change 18:1857–1869CrossRef
Ding ML, Yang XN, Zhao RQ et al (2022) Optimization of territorial space pattern under the goal of carbon neutrality: theoretical framework and practical strategy. J Nat Resour 37(5):1137–1147
Eitelberg DA, van Vliet J, Doelman JC et al (2016) Demand for biodiversity protection and carbon storage as drivers of global land change scenarios. Global Environ Change 40:101–111CrossRef
Evans CD, Peacock M, Baird AJ et al (2021) Overriding water table control on managed peatland greenhouse gas emissions. Nature 593(7860):548–552CrossRef
Fan SL, Zhang L, Zeng ZS et al (2017) Factors influencing land intensive use of development zone in regions with different levels of economic development: a case study in Fujian Province. China Land Sci 31:51–58
He ZC, Zhao CH, Li GY et al (2020) From spatial planning to land use change: difference, current situation, challenge, and future direction. City Plan Rev 044:9–19
Hong C, Burney JA, Pongratz J et al (2021) Global and regional drivers of land-use emissions in 1961–2017. Nature 589:554–561CrossRef
Hong C, Zhao H, Qin Y et al (2022) Land-use emissions embodied in international trade. Science 376:597–603CrossRef
IPCC (2007) Climate Change 2007: the Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Summary for policymakers. Cambridge University Press, Cambridge
IPCC (2007b) Climate Change 2007: impacts, adaptation and vulnerability: contribution of working group II to the Fourth Assessment Report of the Intergovernmental Panel. Cambridge University Press, Cambridge
IPCC (2012) Managing the risks of extreme events and disasters to advance climate change adaptation: special report of the intergovernmental panel on climate change. Cambridge University Press, Cambridge
IPCC (2013) Climate Change 2013: the Physical Science Basis Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge
IPCC (2022) “Mitigation pathways compatible with 1.5°C in the context of sustainable development.” In: Global Warming of 1.5°C: IPCC Special Report on Impacts of Global Warming of 1.5°C above pre-industrial levels in context of strengthening response to climate change, sustainable development, and efforts to eradicate poverty. Cambridge University Press, Cambridge
Jin G, Deng XZ, Zhao XD et al (2018) Spatiotemporal patterns in urbanization efficiency within the Yangtze River Economic Belt between 2005 and 2014. J Geogr Sci 28:1113–1126CrossRef
Li J, Bai J, Ralph O (1998) Assessment of biomass resource availability in China[M]. China Environmental Science Press, Beijing
Liu M, Yang L (2021) Spatial pattern of China’s agricultural carbon emission performance. Ecol Indicat 133:108345CrossRef
Liu X, Vitousek P, Chang Y et al (2015) Evidence for a historic change occurring in China. Environ Sci Technol 50:505–506CrossRef
Poore J, Nemecek T (2018) Reducing food’s environmental impacts through producers and consumers. Science 360:987–992CrossRef
Rudel TK, Coomes OT, Moran E et al (2005) Forest transitions: towards a global understanding of land-use change. Glob Environ Chang 15(1):23–31CrossRef
Tian HQ, Xu RT, Canadell JG et al (2020) A comprehensive quantification of global nitrous oxide sources and sinks. Nature 586(7828):248CrossRef
Verburg PH, Alexander P, Evans T et al (2019) Beyond land cover change: towards a new generation of land use models. Curr Opin Environ Sustainability 38:77–85CrossRef
Wu YL, Zhang P, Yu YY et al (2021) Progress review on and prospects for non-grain cultivated land in China from the perspective of food security. China Land Sci 35:116–124
Zhang BL, Yang QY, Lu CY et al (2011) Effect on economic development of regional land use change indifferent development phase: forty counties in chongqing as the research object. Econ Geogr 31:1539–1544+7
Zhang G, Lu F, Zhao H et al (2017) Residue usage and farmers’ recognition and attitude toward residue retention in China’s croplands. J Agro-Environ Sci 36:981–988
Zhang WJ, Yan SJ, Zhang J et al (2021) Win-win strategy for national food security and agricultural double-carbon goals. Sci Agric Sinica 54:3892–3902
Zhang XX, Wu LY, Ma XZ et al (2022) Dynamic computable general equilibrium simulation of agricultural greenhouse gas emissions in China. J Clean Prod 345:131122CrossRef
Zhao RQ, Huang XJ, Zhong TY et al (2013) Carbon effect evaluation and low-carbon optimization of regional land use. Trans Chin Soc Agric Eng 29:220–229
Zhu XH, Zhang Y, Zhu YY (2023) Regional regulation and interregional coordination of cultivated land protection inChina from the perspective of “greater food” approach. Acta Geogr Sin 78:2147–2162
Metadaten
Titel
The impact of agricultural land use change on agricultural GHG emissions in China
verfasst von
Hu Yi
Jiang Penghui
Li Manchun
Publikationsdatum
01.01.2024
Verlag
Springer Berlin Heidelberg
Erschienen in
Environmental Earth Sciences / Ausgabe 2/2024
Print ISSN: 1866-6280
Elektronische ISSN: 1866-6299
DOI
https://doi.org/10.1007/s12665-023-11369-1

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