The Potential and Technological Approaches of China’s Farmland to Mitigate Climate Change

doi:10.11924/j.issn.1000-6850.casb20190800585

Abstract

Abstract:

Climate change, characterized by global warming, is one of the biggest environmental problems facing human beings, which has a significant impact on agricultural production and food security. To enhance the response and adapting to climate change of crops, increase carbon sequestration, and reduce greenhouse gas emission have become an urgent task for China’s agricultural production. The present study briefly analyzed the current situation of carbon sequestration in China’s agriculture, and summarized the relevant technical systems of coping with climate change in China’s agricultural production. Based on the analysis of the potential and technical approaches in adapting and mitigating climate change in China agricultural production, the research on increasing the potential of agricultural carbon sequestration in the future is prospected to provide a reference for the sustainable development of agriculture in China under the background of climate change.

Key words: agricultural production, climate change, greenhouse gases emission reduction, soil organic carbon sequestration, technical approach

CLC Number:

S162
S19

Ruan Junmei, Song Zhenwei, Wang Quanhui, Wang Li. The Potential and Technological Approaches of China’s Farmland to Mitigate Climate Change[J]. Chinese Agricultural Science Bulletin, 2020, 36(5): 98-102.

References 64

[1]	World Meteorological Organization. WMO Greenhouse Gas Bulletin (GHG Bulletin): The State of Greenhouse Gases in the Atmosphere Based on Global Observations through 2017[R]. World Meteorological Organization (WMO), Global Atmosphere Watch (GAW), Geneva,Switzerland, 2018.
[2]	IPCC. Climate Change 2013: The physical science base. contribution of working group I to the fifth assessment report of the intergovernmental panel on climate change[M]. United Kingdom Cambridge: Cambridge University Press, 2013: 1-300.
[3]	巢清尘, 张永香, 高翔 , 等. 巴黎协定——全球气候治理的新起点[J]. 气候变化研究进展, 2016,12(1):61-67.
[4]	高小升 . 海外学界对中国气候政策的研究评析[J]. 社会主义研究, 2019(3):157-165.
[5]	刘硕, 李玉娥, 秦晓波 , 等. 《巴黎协定》实施细则适应议题焦点解析及后续中国应对措施[J]. 气候变化研究进展, 2019,15(4):1-12.
[6]	Vermeulen S J, Campbell B M, Ingram J S I. Climate Change and Food Systems[J]. Annual Review of Environment and Resources, 2012,37(1):195-222.
[7]	NDRC (National Development and Reform Commission of China). Second National Communication on Climate Change of The People’s Republic of China [EB/OL]. , 2019.
[8]	Bennetzen E H, Smith P, Porter J R . Decoupling of greenhouse gas emissions from global agricultural production:1970-2050[J]. Global Change Biology, 2016,22(2):763-781.
[9]	Wang X H . Changes in CO₂ emissions induced by agricultural inputs in China over 1991-2014[J]. Sustainability, 2016,8(5):414-426.
[10]	杨帆, 孟远夺, 姜义 , 等. 2013年我国种植业化肥施用状况分析[J]. 植物营养与肥料学报, 2015,21(1):217-225.
[11]	Zhang X, Xu X, Liu Y , et al. Global warming potential and greenhouse gas intensity in rice agriculture, driven by high yields and nitrogen use efficiency[J]. Biogeosciences, 2016,13(9):2701-2714.
[12]	米松华, 黄祖辉, 朱奇彪 , 等. 稻田温室气体减排成本收益分析[J]. 浙江农业学报, 2016,28(4):707-716.
[13]	张福锁, 王激清, 张卫峰 , 等. 中国主要粮食作物肥料利用率现状与提高途径[J]. 土壤学报, 2008,45(5):915-924.
[14]	Chai R, Niu Y, Huang L , et al. Mitigation potential of greenhouse gases under different scenarios of optimal synthetic nitrogen application rate for grain crops in China[J]. Nutrient Cycling in Agroecosystems, 2013,96(1):15-28.
[15]	陈晓明, 王程龙, 薄瑞 . 中国农药使用现状及对策建议[J]. 农药科学与管理, 2016,37(2):4-8.
[16]	白若琦, 白朴, 吴益伟 , 等. 种植业固碳减排潜力和技术对策研究[J]. 江苏农业科学, 2017,45(22):279-283.
[17]	赵建宁, 张贵龙, 杨殿林 . 中国粮食作物秸秆焚烧释放碳量的估算[J]. 农业环境科学学报, 2011,30(4):812-816.
[18]	杭晓宁 . 稻作方式和秸秆还田对稻麦产量和温室气体排放的影响研究[D]. 南京:南京农业大学, 2015.
[19]	Xu H, Cai Z C, Li X P , et al. Effect of antecedent soil water regime and rice straw application time on CH₄ emission from rice cultivation[J]. Soil Research, 2000,38(1):1-12.
[20]	Corton T M, Bajita J B, Grospe F S , et al. Methane emission from irrigated and intensively managed rice fields in central Luzon (Philippines)[J]. Nutrient Cycling in agroecosystems, 2000,58(1/2/3):37-53.
[21]	Yan X Y, Akiyama H, Yagi K , et al. Global estimations of the inventory and mitigation potential of methane emissions from rice cultivation conducted using the 2006 Intergovernmental Panel on Climate Change guidelines[J]. Global Biogeochemical Cycles, 2009,23(2):627-634.
[22]	农业农村部规划设计研究院设施农业研究所. 我国设施园艺装备发展现状和建议[J]. 农机科技推广, 2019,195(1):29-30.
[23]	刘文科, 刘喜明, 杨其长 . 减排工业源CO₂的一种方法——设施园艺固碳[J]. 科技导报, 2013,31(14):11.
[24]	Vourdoubas J . Overview of the use of sustainable energies in agricultural greenhouses[J]. Journal of Agricultural Science, 2016,8(3):36.
[25]	李波, 张俊飚 . 我国农作物碳汇的阶段特征与空间差异研究[J]. 湖北农业科学, 2013,52(5):1229-1233.
[26]	Lal R . Agricultural activities and the global carbon cycle[J]. Nutrient Cycling in Agroecosystems, 2004,70(2):103-116.
[27]	Song G H, Li L Q, Pan G X , et al. Topsoil organic carbon storage of China and its loss by cultivation[J]. Biogeochemistry, 2005,74(1):47-62.
[28]	Qin Z C, Huang Y, Zhuang Q L . Soil organic carbon sequestration potential of cropland in China[J]. Global Biogeochemical Cycles, 2013,27(3):711-722.
[29]	Tang H J, Qiu J J, Van Ranst E , et al. Estimations of soil organic carbon storage in cropland of China based on DNDC model[J]. Geoderma, 2006,134(1-2):200-206.
[30]	Huang Y, Sun W J . Changes in topsoil organic carbon of croplands in mainland China over the last two decades[J]. Chinese Sci Bull, 2006,51(15):1785-1803.
[31]	Yu Y Q, Huang Y, Zhang W. Modeling soil organic carbon change in croplands of China, 1980-2009[J]. Global Planet Change, 2012,82-83:115-128.
[32]	陈镜明 . 全球陆地碳汇的遥感和优化计算方法[M]. 北京: 科学出版社, 2015: 195-232.
[33]	赵永存, 徐胜祥, 王美艳 , 等. 中国农田土壤固碳潜力与速率:认识、挑战与研究建议[J]. 中国科学院院刊, 2018,33(2):191-197.
[34]	史思伟 . 长期施用生物炭对土壤碳库的影响[D]. 北京:中国农业科学院, 2019.
[35]	李昊昱, 孟兆良, 庞党伟 , 等. 周年秸秆还田对农田土壤固碳及冬小麦-夏玉米产量的影响[J]. 作物学报, 2019,45(6):893-903.
[36]	张茂鑫 . 东北旱田不同农作情景下土壤有机碳变化及固碳潜力的模拟研究[D]. 沈阳:沈阳农业大学, 2018.
[37]	梁丰 . 我国典型农田土壤固碳效率的时空差异特征及驱动因素[D]. 北京:中国农业科学院, 2018.
[38]	Sainju U M, Senwo Z N, Nyakatawa E Z , et al. Tillage, Cropping Systems, and Nitrogen Fertilizer Source Effects on Soil Carbon Sequestration and Fractions[J]. Journal of Environmental Quality, 2008,37(3):880-888.
[39]	徐尚起, 黄光辉, 李永 , 等. 农业措施对农田土壤碳影响研究进展[J]. 中国农学通报, 2011,27(8):259-264.
[40]	邹晓霞, 李玉娥, 高清竹 , 等. 中国农业领域温室气体主要减排措施研究分析[J]. 生态环境学报, 2011,20(8/9):1348-1358.
[41]	陈兆波, 董文, 霍治国 , 等. 中国农业应对气候变化关键技术研究进展及发展方向[J]. 中国农业科学, 2013,46(15):3097-3104.
[42]	Shao G, Deng S, Liu N , et al. Effects of controlled irrigation and drainage on growth, grain yield and water use in paddy rice[J]. European Journal of Agronomy, 2015,53:1-9.
[43]	Tao H, Brueck H, Dittert K , et al. Growth and yield formation for rice (Oryza sativa L.) in the water-saving ground cover rice production system (GCRPS)[J]. Field Crops Research, 2006,95:1-12.
[44]	Lampayan R, Rejesus R, Singleton G , et al. Adoption and economics of alternate wetting and drying water management for irrigated lowland rice[J]. Field Crops Research, 2015,170:95-108.
[45]	王濮, 鲁来清, 王润正 , 等. 河北吴桥小麦-玉米一年两作超高产探索[J]. 中国农业科技导报, 2000,2(3):12-15.
[46]	张盼峰, 汪江涛, 焦念元 , 等. 轮耕与隔畦灌溉对麦玉两熟作物生长和水分利用效率的影响[J]. 作物杂志, 2013(6):118-122.
[47]	胡梦芸, 张正斌, 徐萍 , 等. 亏缺灌溉下小麦水分利用效率与光合产物积累转运的相关研究[J]. 作物学报, 2007,33(11):1884-1891.
[48]	康绍忠, 史文娟, 胡笑涛 , 等. 调亏灌溉对于玉米生理指标及水分利用效率的影响[J]. 农业工程学报, 1998,14(4):82-87.
[49]	买自珍, 蒋儒龄, 袁丕成 , 等. 宁夏中部扬黄灌溉区地膜玉米膜孔灌溉技术研究[J]. 干旱地区农业研究, 2011,29(2):53-58.
[50]	张昊, 郝春雷, 孟繁盛 , 等. 膜下滴灌条件下不同灌水量对玉米产量及土壤水分的影响[J]. 作物杂志, 2016(1):105-109.
[51]	张婷, 吴普特, 赵西宁 , 等. 垄沟灌溉种植对玉米光合特性及产量的影响[J]. 灌溉排水学报, 2013,32(1):96-98.
[52]	李怀有, 赵安成, 白文媛 , 等. 高塬沟壑区集雨节灌发展模式与对策[J]. 节水灌溉, 2001(3):24-26.
[53]	李卓, 刘淑亮, 孙然好 , 等. 黄淮海地区耕地复种指数的时空格局演变[J]. 生态学报, 2018,38(12):4454-4460.
[54]	刘晓永 . 中国农业生产中的养分平衡与需求研究[D]. 北京:中国农业科学院, 2018.
[55]	余智涵, 苏世伟 . 生物质能源产业发展研究动态与展望[J]. 中国林业经济, 2019(3):5-7,12.
[56]	柳家友, 闫海霞, 赵全花 , 等. 黄淮海南部优质抗逆玉米新品种选育技术探讨[J]. 山西农业科学, 2018,46(2):167-171.
[57]	江添茂 . 双晚免耕栽培技术效果及方法要点[J]. 福建稻麦科技, 2005,23(2):15-16.
[58]	于久全 . 玉米膜下滴灌高产栽培技术规程[J]. 现代农业, 2012(10):46-47.
[59]	贺军勇, 刘伟 . 新疆哈密市棉花膜下滴灌高产栽培技术[J]. 中国种业, 2011(10):75-76.
[60]	张艳君 . 黑背山小流域保护性耕作防治坡耕地水土流失效应的研究[J]. 水土保持通报, 2012,32(1):103-105.
[61]	崔海信, 姜建芳, 刘琪 . 论植物营养智能化递释系统与精准施肥[J]. 植物营养与肥料学报, 2011,17(2):494-499.
[62]	王永强, 陈亚辉, 于洪军 . 芹菜病虫害防治技术[J]. 西北园艺:蔬菜专刊, 2010(3):39-40.
[63]	陈萌山 . 把加快发展节水农业作为建设现代农业的重大战略举措[J]. 农业经济问题, 2011(2):4-7.
[64]	孙扬越, 申双和 . 作物生长模型的应用研究进展[J]. 中国农业气象, 2019,40(7):444-459.