[1] |
ALVES M, GRIGNARD B, MEREAU R, et al., 2017. Organocatalyzed coupling of carbon dioxide with epoxides for the synthesis of cyclic carbonates: catalyst design and mechanistic studies[J]. Catalysis Science & Technology, 7(13): 2651-2684.
|
[2] |
ANDERSON K, PETERS G, 2016. The trouble with negative emissions[J]. Science, 354(6309): 182-183.
PMID
|
[3] |
BAI Z, WANG X, WU X, et al., 2021. China requires region-specific manure treatment and recycling technologies[J]. Circular Agricultural Systems, 1(1): 1-8.
|
[4] |
BEERLING D J, KANTZAS E P, LOMAS M R, et al., 2020. Potential for large-scale CO2 removal via enhanced rock weathering with croplands[J]. Nature, 583(7815): 242-248.
DOI
URL
|
[5] |
BELLER M, BORNSCHEUER U T, 2014. CO2 fixation through hydrogenation by chemical or enzymatic methods[J]. Angewandte Chemie International Edition, 53(18): 4527-4528.
DOI
URL
|
[6] |
BIRDJA Y Y, PÉREZ-GALLENT E, FIGUEIREDO M C, et al., 2019. Advances and challenges in understanding the electrocatalytic conversion of carbon dioxide to fuels[J]. Nature Energy, 4(9): 732-745.
DOI
URL
|
[7] |
CAI T, SUN H, QIAO J, et al., 2021. Cell-free chemoenzymatic starch synthesis from carbon dioxide[J]. Science, 373(6562): 1523-1527.
DOI
PMID
|
[8] |
CHEN J M, 2021. Carbon neutrality: Toward a sustainable future[J]. The Innovation, 2(3): 1-2.
|
[9] |
DAWAR K, KHAN A, SARDAR K, et al., 2021. Effects of the nitrification inhibitor nitrapyrin and mulch on N2O emission and fertilizer use efficiency using 15N tracing techniques[J]. Science of The Total Environment, 757: 143739.
|
[10] |
DIAZ-ELSAYED N, REZAEI N, GUO T, et al., 2019. Wastewater-based resource recovery technologies across scale: A review[J]. Resources, Conservation and Recycling, 145: 94-112.
DOI
URL
|
[11] |
DISSANAYAKE P D, YOU S, IGALAVITHANA A D, et al., 2020. Biochar-based adsorbents for carbon dioxide capture: A critical review[J]. Renewable and Sustainable Energy Reviews, 119: 109582.
|
[12] |
HARINDINTWALI J D, ZHOU J, MUHOZA B, et al., 2021. Integrated eco-strategies towards sustainable carbon and nitrogen cycling in agriculture[J]. Journal of Environmental Management, 293: 112856.
|
[13] |
HOU S L, DONG J, ZHAO B, 2020. Formation of C-X bonds in CO2 chemical fixation catalyzed by metal-organic frameworks[J]. Advanced Materials, 32(3): 1806163. 1-1806163.14.
|
[14] |
IPCC, 2021. Climate change 2021:the physical science basis. Contribution of working group I to the sixth assessment report of the intergovernmental panel on climate change[M]. Cambridge: Cambridge Press.
|
[15] |
JIN H, OKAMOTO T, ISHIDA M, 1998. Development of a novel chemical-looping combustion: synthesis of a looping material with a double metal oxide of CoO-NiO[J]. Energy & Fuels, 12(6): 1272-1277.
DOI
URL
|
[16] |
KASTNER M, MILTNER A, 2018. SOM and microbes-what is left from microbial life. The future of soil carbon[M]. Massachusetts: Academic Press:125- 163.
|
[17] |
LEHMANN J, 2007. A handful of carbon[J]. Nature, 447(7141): 143-144.
DOI
URL
|
[18] |
LEÓN L F, LAM D C, SWAYNE D A, et al., 2000. Integration of a nonpoint source pollution model with a decision support system[J]. Environmental Modelling & Software, 15(3): 249-255.
|
[19] |
LI K, PENG B, PENG T, 2016. Recent advances in heterogeneous photocatalytic CO2 conversion to solar fuels[J]. ACS Catalysis, 6(11): 7485-7527.
DOI
URL
|
[20] |
LI S, GAO L, JIN H, 2017. Realizing low life cycle energy use and GHG emissions in coal based polygeneration with CO2 capture[J]. Applied Energy, 194: 161-171.
DOI
URL
|
[21] |
LIANG C, SCHIMEL J P, JASTROW J D, 2017. The importance of anabolism in microbial control over soil carbon storage[J]. Nature Microbiology, 2(8): 1-6.
|
[22] |
LIANG D, LU X, ZHUANG M, et al., 2021. China’s greenhouse gas emissions for cropping systems from 1978-2016[J]. Scientific Data, 8(1): 171.
DOI
URL
|
[23] |
LIU R, XU F, ZHANG P, et al., 2016. Identifying non-point source critical source areas based on multi-factors at a basin scale with SWAT[J]. Journal of Hydrology, 533: 379-388.
DOI
URL
|
[24] |
LIU Y Q, WANG H R, JIANG Z M, et al., 2021. Genomic basis of geographical adaptation to soil nitrogen in rice[J]. Nature, 590(7847): 600-605.
DOI
URL
|
[25] |
LIU Z H, WANG K, CHEN Y, et al., 2020. Third-generation biorefineries as the means to produce fuels and chemicals from CO2[J]. Nature Catalysis, 3(3): 274-288.
DOI
URL
|
[26] |
MAHANTA S K, GARCIA S C, ISLAM M R, 2020. Forage based feeding systems of dairy animals: Issues, limitations and strategies[J]. Range Management & Agroforestry, 41(2): 188-199.
|
[27] |
MATHUR M, AWASTHI S, 2016. Carbon neutral village/cluster: a conceptual framework for envisioning[J]. Current Science, 110(7): 1208-1215.
|
[28] |
SHAHEEN S M, NIAZI N K, HASSAN N E E, et al., 2019. Wood-based biochar for the removal of potentially toxic elements in water and wastewater: A critical review[J]. International Materials Reviews, 64(4): 216-247.
DOI
URL
|
[29] |
SHANG Z, ABDALLA M, XIA L, et al., 2021. Can cropland management practices lower net greenhouse emissions without compromising yield?[J]. Global Change Biology, 27(19): 4657-4670.
DOI
PMID
|
[30] |
SIEDT M, SCHÄFFER A, SMITH K E C, et al., 2021. Comparing straw, compost, and biochar regarding their suitability as agricultural soil amendments to affect soil structure, nutrient leaching, microbial communities, and the fate of pesticides[J]. Science of The Total Environment, 751: 141607.
|
[31] |
SUBHARAT S, SHU D, ZHENG T, et al., 2016. Vaccination of sheep with a methanogen protein provides insight into levels of antibody in saliva needed to target ruminal methanogens[J]. PLoS One, 11(7): e0159861.
|
[32] |
TURSI A, 2019. A review on biomass: importance, chemistry, classification, and conversion[J]. Biofuel Research Journal, 6(2): 962-979.
DOI
URL
|
[33] |
UNFCCC, 2015. Paris Agreement (United Nations Framework Convention on Climate Change)[EB/OL]. [2015-12-12]. https://unfccc.int/process-and-meetings/the-paris-agreement/the-paris-agreement.
|
[34] |
WANG C K, LUO X Z, ZHANG H, 2013. Differences between the shares of greenhouse gas emissions calculated with GTP and GWP for major countries[J]. Climate Change Research, 9(1): 49-54.
|
[35] |
WANG F, HARINDINTWALI J D, YUAN Z Z, et al., 2021. Technologies and perspectives for achieving carbon neutrality[J]. The Innovation, 2(4): 100180.
|
[36] |
WANG M, JANSSEN P H, SUN X Z, et al., 2013. A mathematical model to describe in vitro kinetics of H2 gas accumulation[J]. Animal Feed Science and Technology, 184(1-4): 1-16.
DOI
URL
|
[37] |
WANG Y Q, BAI R, DI H J, et al., 2018. Differentiated mechanisms of biochar mitigating straw-induced greenhouse gas emissions in two contrasting paddy soils[J]. Frontiers in Microbiology, 9: 2566.
DOI
URL
|
[38] |
WMO, 2021. World Meteorological Organization (WMO) statement on the state of the global climate 2020 [EB/OL]. [2022-01-24]. https://public.wmo.int/en/our-mandate/climate/wmo-statement-state-of-global-climate
|
[39] |
WU F C, LI F B, ZHAO X L, et al., 2022. Meet the challenges in the “Carbon Age”[J]. Carbon Research, 1(1): 1-2.
DOI
URL
|
[40] |
YIN Y, YANG C, LI M T, et al., 2021. Research progress and prospects for using biochar to mitigate greenhouse gas emissions during composting: A review[J]. Science of The Total Environment, 798: 149294.
|
[41] |
ZHANG R, XIE W M, YU H Q, et al., 2014. Optimizing municipal wastewater treatment plants using an improved multi-objective optimization method[J]. Bioresource Technology, 157: 161-165.
DOI
PMID
|
[42] |
ZHONG Y H, JIANG M, MIDDLETON B A, 2020. Effects of water level alteration on carbon cycling in peatlands[J]. Ecosystem Health and Sustainability, 6(1): 199-227.
|
[43] |
卞荣军, 李恋卿, 2021. 生物质废弃物处理与农业碳中和[J]. 科学, 73(6): 22-26, 4.
|
|
BIAN R J, LI L Q, 2021. Waste Biomass Treatment and Carbon Neutrality[J]. Science, 73(6): 22-26, 4.
DOI
URL
|
[44] |
陈治池, 何强, 蔡然, 等, 2022. 碳中和趋势下数学模拟在污水处理系统中的发展与综合应用[J]. 中国环境科学, 42(6): 2587-2602.
|
|
CHEN Z C, HE Q, CAI R, et al., 2022. The development and comprehensive application of mathematical simulation in sewage treatment system under the trend of carbon neutralization[J]. China Environmental Science, 42(6): 2587-2602.
|
[45] |
程琨, 潘根兴, 2021. 农业与碳中和[J]. 科学, 73(6): 8-12, 4.
|
|
CHENG K, PAN G X, 2021. Agriculture and Carbon Neutrality[J]. Science, 73(6): 8-12, 4.
DOI
URL
|
[46] |
贺斌, 胡茂川, 2022. 广东省各区县农业面源污染负荷估算及特征分析[J]. 生态环境学报, 31(4): 771-776.
|
|
HE B, HU M C, 2022. Evaluation of agriculture non-point pollution load and its characteristics in all districts and counties of Guangdong[J]. Ecology and Environmental Sciences, 31(4): 771-776.
|
[47] |
廖秋阳, 2022. 基于碳中和背景下的几种农村污水处理节能技术运用[J]. 河南科技, 41(3): 124-127.
|
|
LIAO Q Y, 2022. Application of energy-saving technologies in rural sewage treatment based on carbon neutralization[J]. Henan Science and Technology, 41(3): 124-127.
|
[48] |
任杰, 曾安平, 2021. 基于二氧化碳的生物制造: 从基础研究到工业应用的挑战[J]. 合成生物学, 2(6): 854-862.
|
|
REN J, ZENG A P, 2021. CO2 based biomanufacturing: From basic research to industrial application[J]. Synthetic Biology Journal, 2(6): 854-862.
|
[49] |
宋云华, 2017. 广东渔业光伏项目经济环保效益分析[J]. 价值工程, 36(7): 103-104.
|
|
SONG Y H, 2017. Analysis on economic and environmental benefits of Guangdong Fishery Photovoltaic Project[J]. Value Engineering, 36(7): 103-104.
|
[50] |
谭天伟, 陈必强, 张会丽, 等, 2021. 加快推进绿色生物制造助力实现“碳中和”[J]. 化工进展, 40(3): 1137-1141.
|
|
TAN T W, CHEN B Q, ZHANG H L, et al., 2021. Accelerate promotion of green bio-manufacturing to help achieve “carbon neutrality”[J]. Chemical Industry and Engineering Progress, 40(3): 1137-1141.
|
[51] |
唐博文, 2022. 从国际经验看中国农业温室气体减排路径[J]. 世界农业, 515(3):18-24.
|
|
TANG B W, 2022. China’s agricultural greenhouse gas emission reduction path from international experience[J]. World Agriculture, 515(3):18-24.
|
[52] |
汤俊超, 吴宜文, 张姚, 等, 2022. 浅谈“光伏+农业”产业的发展模式[J]. 中国农学通报, 38(11): 144-152.
|
|
TANG J C, WU Y W, ZHANG Y, et al., 2022. A brief introduction on the industrial development mode of photovoltaic agriculture[J]. Chinese Agricultural Science Bulletin, 38(11): 144-152.
|
[53] |
王斌, 李玉娥, 蔡岸冬, 等, 2022. 碳中和视角下全球农业减排固碳政策措施及对中国的启示[J]. 气候变化研究进展, 18(1): 110-118.
|
|
WANG B, LI Y E, CAI A D, et al., 2022. Global policies in agricultural greenhouse gas reduction and carbon sequestration and their enlightenment to China in the view of carbon neutrality[J]. Climate Change Research, 18(1): 110-118.
|
[54] |
王萌, 周丽丽, 耿润哲, 2020. 农业面源污染治理的技术与政策研究进展[J]. 环境与可持续发展, 45(1): 98-103.
|
|
WANG M, ZHOU L L, GENG R Z, 2020. A review: the technology and policy design of agricultural non-point source pollution management[J]. Environment and Sustainable Development, 45(1): 98-103.
|
[55] |
王绍军, 张明, 宋烨, 等, 2020. 聊城食用菌产业发展现状与建议[J]. 中国果菜, 40(10): 69-74.
|
|
WANG S J, ZHANG M, SONG Y, et al., 2020. Development status and suggestions of edible fungi industry in Liaocheng City[J]. China Fruit & Vegetable, 40(10): 69-74.
|
[56] |
武淑霞, 刘宏斌, 刘申, 等, 2018. 农业面源污染现状及防控技术[J]. 中国工程科学, 20(5): 23-30.
|
|
WU S X, LIU H B, LIU S, et al., 2018. Review of current situation of agricultural non-point source pollution and its prevention and control technologies[J]. Strategic Study of CAE, 20(5): 23-30.
|
[57] |
夏军, 翟晓燕, 张永勇, 2012. 水环境非点源污染模型研究进展[J]. 地理科学进展, 31(7): 941-952.
|
|
XIA J, ZHAI X Y, ZHANG Y Y, 2012. Progress in the research of water environmental nonpoint source pollution models[J]. Progress in Geography, 31(7): 941-952.
DOI
|
[58] |
谢立勇, 杨育蓉, 赵洪亮, 等, 2022. “双碳”战略背景下农业与农村减排技术路径分析[J]. 中国生态农业学报(中英文), 30(4): 527-534.
|
|
XIE L Y, YANG Y R, ZHAO H L, et al., 2022. Technical pathways of mitigating greenhouse gases emission from agriculture and rural areas under double-carbon strategy[J]. Chinese Journal of Eco-Agriculture, 30(4): 527-534.
|
[59] |
杨林章, 吴永红, 2018. 农业面源污染防控与水环境保护[J]. 中国科学院院刊, 33(2): 168-176.
|
|
YANG L Z, WU Y H, 2018. Prevention and control of agricultural non-point source pollution and aquatic environmental protection[J]. Bulletin of Chinese Academy of Sciences, 33(2): 168-176.
|
[60] |
张岳, 葛铜岗, 孙永利, 等, 2021. 基于城镇污水处理全流程环节的碳排放模型研究[J]. 中国给水排水, 37(9): 65-74.
|
|
ZHANG Y, GE T G, SUN Y L, et al., 2021. Research on carbon emission model based on the whole process of urban sewage treatment[J]. China Water & Wastewater, 37(9): 65-74.
|