[1] Juliusson G. Globalization, climate change, and human health. The New England Journal of Medicine, 2013, 369: 96 [2] 邹才能, 何东博, 贾成业, 等. 世界能源转型内涵、路径及其对碳中和的意义. 石油学报, 2021, 42(2): 233-247 [3] Panwar NL, Kaushik SC, Surendra K. Role of renewable energy sources in environmental protection: A review. Renewable and Sustainable Energy Reviews, 2011, 15: 1513-1524 [4] 吴贵辉. 大力发展清洁能源 推进电力可持续发展. 电网与清洁能源, 2008(9): 1-2 [5] 赵颖, 王一波, 李海玲. 2022年中国光伏技术发展报告(简版). 太阳能, 2022(4): 5-11 [6] ISO. Environmental Management-Life Cycle Assessment Requirements and Guidelines[EB/OL]. (2018-07-16)[2022-12-12]. https://www.iso.org/obp/ui/#iso:std:iso:14044:ed-1:v1:en [7] Parida B, Iniyan S, Goic R. A review of solar photovoltaic technologies. Renewable and Sustainable Energy Reviews, 2011, 15: 1625-1636 [8] 郭敏晓. 风力、光伏及生物质发电的生命周期CO2排放核算. 硕士论文. 北京: 清华大学, 2012 [9] 中华人民共和国国家统计局. 中国统计年鉴 2021. 北京: 中国统计出版社, 2021 [10] 水电水利规划设计总院. 2016中国可再生能源发展报告. 北京: 水电水利规划设计总院, 2017 [11] 苏树辉, 刘吉臻, 韩文科. 国际清洁能源产业发展报告(2019). 北京: 中国言实出版社, 2019 [12] 李铮, 郭小江, 申旭辉, 等. 我国海上风电发展关键技术综述. 发电技术, 2022, 43(2):186-197 [13] Wang CN, Nguyen NA, Dang TT. Offshore wind power station (OWPS) site selection using a two-stage MCDM-based spherical fuzzy set approach. Scientific Reports, 2022, 12: 4260 [14] 国家能源局. 2021年光伏发电建设运行情况[EB/OL]. (2022-03-09)[2022-10-10]. http://www.nea.gov.cn/2022-03/09/c_1310508114.html. [15] 金凤. 新方法重塑制备流程 钙钛矿太阳能电池刷新世界纪录. 科技日报, 2022-05-25(005) [16] Wang L, Tang Y, Zhang S, et al. Energy yield analysis of different bifacial PV (photovoltaic) technologies: TOPCon, HJT, PERC in Hainan. Solar Energy, 2022, 238: 258-263 [17] 翁琳, 陈剑波. 光伏系统基于全生命周期碳排放量计算的环境与经济效益分析. 上海理工大学学报, 2017, 39(3): 282-288 [18] Li H, Jiang HD, Dong KY, et al. A comparative analysis of the life cycle environmental emissions from wind and coal power: Evidence from China. Journal of Cleaner Production, 2020, 248: 119192 [19] 王鑫淼, 马志勇, 周旺潇, 等. 光伏发电系统碳中和及其影响因素. 资源科学, 2022, 44(8):1735-1744 [20] Sun YF, Chang JF, Fang JY. Above-and belowground net-primary productivity: A field-based global database of grasslands. Ecology, 2022, 104: e3904 [21] 许骞骞, 曹先磊, 孙婷, 等. 中国森林碳汇潜力与增汇成本评估——基于Meta分析方法. 自然资源学报, 2022, 37(12): 3217-3233 [22] Santoyo-Castelazo E, Solano-Olivares K, Martinez E, et al. Life cycle assessment for a grid-connected multi-crystalline silicon photovoltaic system of 3 kWp: A case study for Mexico. Journal of Cleaner Production, 2021, 316: 128314 [23] Ivan T, Herrmann AM. Does it matter which Life Cycle Assessment (LCA) tool you choose? A comparative assessment of SimaPro and GaBi. Journal of Cleaner Production, 2015, 86 : 163-169 [24] Crawford RH. Life cycle energy and greenhouse emissions analysis of wind turbines and the effect of size on energy yield. Renewable and Sustainable Energy Reviews, 2009, 13: 2653-2660 [25] Brice T, Francis M. Life cycle analysis of 4.5 MW and 250W wind turbines. Renewable and Sustainable Energy Reviews, 2009, 13: 2104-2110 [26] Peter G, Klaus R. Life cycle assessment of wind power: Comprehensive results from a state-of-the-art approach. The International Journal of Life Cycle Assessment, 2013, 18: 37-48 [27] Kerstin B, Oebels SP. Life cycle assessment of an onshore wind farm located at the northeastern coast of Brazil. Renewable Energy, 2013, 53: 60-70 [28] Sergio A, María S, Agustín R. Product and corporate carbon footprint using the compound method based on financial accounts: The case of Osorio wind farms. Applied Energy, 2015, 139: 196-204 [29] Alexandra B, Alexis L, Stig IO. Life cycle assessment of onshore and offshore wind energy-from theory to application. Applied Energy, 2016, 180: 327-337 [30] Raadal HL, Vold BI, Myhr A, et al. GHG emissions and energy performance of offshore wind power. Renewable Energy, 2014, 66: 314-324 [31] Britta R, Burcu Ö, Martin K. Greenhouse gas emissions from electricity generated by offshore wind farms. Renewable Energy, 2014, 72: 428-438 [32] Santoyo-Castelazo E, Gujba H, Azapagic A. Life cycle assessment of electricity generation in Mexico. Energy, 2011, 36: 1488-1499 [33] Michaja P, Anders A, Florian H, et al. Understanding future emissions from low-carbon power systems by integration of life-cycle assessment and integrated energy modelling. Nature Energy, 2017, 2: 939-945 [34] Antonio DR, Michael H, Ruben A, et al. Prospective CO2 emissions from energy supplying systems: Photovoltaic systems and conventional grid within Spanish frame conditions. The International Journal of Life Cycle Assessment, 2010, 15: 557-566 [35] Markus G, Strfan B, Richard F. Comparative analysis of environmental impacts of maize-biogas and photovoltaics on a land use basis. Solar Energy, 2010, 84: 1255-1263 [36] Nishimura A, Hayashi Y, Tanaka K, et al. Life cycle assessment and evaluation of energy payback time on high-concentration photovoltaic power generation system. Applied Energy, 2009, 87: 2797-2807 [37] Ito M, Kudo M, Nagura M. A comparative study on life cycle analysis of 20 different PV modules installed at the Hokuto mega-solar plant. Progress in Photovoltaics, 2011, 19: 878-886 [38] Andreas S, Mercedes RG, Roberto VR, et al. Life-cycle assessment of a photovoltaic system in Catalonia (Spain). Renewable and Sustainable Energy Reviews, 2011, 15: 3888-3896 [39] Umberto D, Stefania P, Francesco Z, et al. Life cycle assessment of a ground-mounted 1778 kWp photovoltaic plant and comparison with traditional energy production systems. Applied Energy, 2012, 97: 930-943 [40] De Wild S, Mariska J. Energy payback time and carbon footprint of commercial photovoltaic systems. Solar Energy Materials and Solar Cells, 2013, 119: 296-305 [41] Mohr NJ, Meijer A, Huijbregts MAJ, et al. Environmental life cycle assessment of roof-integrated flexible amorphous silicon/nanocrystalline silicon solar cell laminate. Progress in Photovoltaics: Research and Applications, 2013, 21: 802-815 [42] Kim BJ, Lee JY, Kim KH, et al. Evaluation of the environmental performance of sc-Si and mc-Si PV systems in Korea. Solar Energy, 2014, 99: 100-114 [43] Yue DJ, You FQ, Darling SB. Domestic and overseas manufacturing scenarios of silicon-based photovoltaics: Life cycle energy and environmental comparative analysis. Solar Energy, 2014, 105: 669-678 [44] Constantino G, Freitas M, Fidelis N, et al. Adoption of photovoltaic systems along a sure path: A life cycle assessment study applied to the analysis of GHG emission impacts. Energies, 2018, 11: 2806 [45] Luo W, Khoo YS, Kumar A, et al. A comparative life-cycle assessment of photovoltaic electricity generation in Singapore by multicrystalline silicon technologies. Solar Energy Materials and Solar Cells, 2018, 174: 157-162 [46] Eskew J, Ratledge M, Wallace M, et al. An environmental life cycle assessment of rooftop solar in Bangkok, Thailand. Renewable Energy, 2018, 123: 781-792 [47] Mahmoudi S, Huda N, Alavi Z, et al. End-of-life photovoltaic modules: A systematic quantitative literature review. Resources, Conservation and Recycling, 2019, 146: 1-16 [48] Rahman MM, Alam CS, Ahsan TA. A life cycle assessment model for quantification of environmental footprints of a 3.6 kWp photovoltaic system in Bangladesh. International Journal of Renewable Energy Development, 2019, 8: 113-118 [49] Cabo FG, Nizetic S, Giama E, et al. Techno-economic and environmental evaluation of passive cooled photovoltaic systems in Mediterranean climate conditions. Applied Thermal Engineering, 2020, 169: 114947 [50] Xue B, Ma ZX, Geng Y, et al. A life cycle co-benefits assessment of wind power in China. Renewable and Sustainable Energy Reviews, 2015, 41: 338-346 [51] Zhao XL, Cai Q, Zhang SF, et al. The substitution of wind power for coal-fired power to realize China’s CO2 emissions reduction targets in 2020 and 2030. Energy, 2017, 120: 164-178 [52] Xu L, Pang MY, Zhang LX, et al. Life cycle assessment of onshore wind power systems in China. Resources, Conservation & Recycling, 2018, 132: 361-368 [53] Yang JH, Chang Y, Zhang LX, et al. The life-cycle energy and environmental emissions of a typical offshore wind farm in China. Journal of Cleaner Production, 2018, 180: 316-324 [54] 杨梦斐. 梯级水电工程的环境生态累积效应及生命周期评价研究. 硕士论文. 武汉: 武汉大学, 2013 [55] Fu YY, Liu X, Yuan ZW. Life-cycle assessment of multi-crystalline photovoltaic(PV) systems in China. Journal of Cleaner Production, 2015, 86: 180-190 [56] Hou GF, Sun HH, Jiang ZY, et al. Life cycle assessment of grid-connected photovoltaic power generation from crystalline silicon solar modules in China. Applied Energy, 2016, 164: 882-890 [57] Hong JL. Life cycle assessment of multicrystalline silicon photovoltaic cell production in China. Solar Energy, 2016, 133: 283-293 [58] 何津津. 基于生命周期评价的光伏发电碳排放研究. 硕士论文. 南京: 南京航空航天大学, 2017 [59] Wu PS, Ma XM, Ji JP, et al. Review on life cycle assessment of greenhouse gas emission profit of solar photovoltaic systems. Energy Procedia, 2017, 105: 1289-1294 [60] Jia XJ, Lv F, Li P, et al. Life-cycle assessment of p-type multi-Si back surface field (BSF) solar module in China of 2019. Solar Energy, 2020, 196: 207-216 [61] 蒋宽宽. 单晶硅电池组件-光伏发电全生命周期碳排放. 智能城市, 2021, 7(10): 117-118 [62] 彭程, 彭才德, 高洁, 等. 新时代水电发展展望. 水力发电, 2021, 47(8): 1-3 [63] 三胜咨询. 中国风电产业发展现状及前景展望(下). 电器工业, 2019(9): 32-46 [64] 赵若楠, 董莉, 白璐, 等. 光伏行业生命周期碳排放清单分析. 中国环境科学, 2020, 40(6): 2751-2757 |