[1]CAPURSO T,STEFANIZZI M,TORRESI M,et al. Perspective of the role of hydrogen in the 21st century energy transition[J]. Energy Conversion and Management,2022,251:114898. [2]XIA H,DAI L,SUN L,et al. Analysis of the spatiotemporal distribution pattern and driving factors of renewable energy power generation in China[J]. Economic Analysis and Policy,2023,80:414-428. [3]孟鑫,陈茂林,王雄正,等. 可再生能源大规模制氢系统最优效率控制方法[J]. 湖南电力,2023,43(3):2-8. [4]赵娜,张莲,王士彬,等. 并网型风光氢储微电网容量优化配置[J]. 湖南电力,2023,43(4):48-55. [5]张博,孙旭东,刘颖,等. 能源新技术新兴产业发展动态与2035战略对策[J]. 中国工程科学,2020,22(2):38-46. [6]俞红梅,邵志刚,侯明,等. 电解水制氢技术研究进展与发展建议[J]. 中国工程科学,2021,23(2):146-152. [7]祁风华,胡桂平,孙玉霞. 中压水电解制氢装置的液位控制[J]. 湖南电力,2002,22(2):49-50,54. [8]杨春和,王同涛. 深地储能研究进展[J]. 岩石力学与工程学报,2022,41(9):1729-1759. [9]王贺武,欧阳明高,李建秋,等. 中国氢燃料电池汽车技术路线选择与实践进展[J]. 汽车安全与节能学报,2022,13(2):211-224. [10]ISHAQ H,DINCER I,CRAWFORD C. A review on hydrogen production and utilization:Challenges and opportunities[J]. International Journal of Hydrogen Energy,2022,47(62):26238-26264. [11]李华洋,谭强,陈家傲,等. 基于文献计量法的中国氢能研究历程[J/OL]. 太阳能学报:1-11(2023-08-01)[2023-9-11].https://DOI:10.19912/j.0254-0096.tynxb.2023-0138. [12]BUTTLER A,SPLIETHOFF H. Current status of water electrolysis for energy storage,grid balancing and sector coupling via power-to-gas and power-to-liquids:A review[J]. Renewable & Sustainable Energy Reviews,2018,82:2440-2454. [13]SHIVA KUMAR S,HIMABINDU V. Hydrogen production by PEM water electrolysis-A review[J]. Materials Science for Energy Technologies,2019,2(3):442-454. [14]KHALIGH V,GHEZELBASH A,ZAREI M,et al. Efficient integration of alkaline water electrolyzer-A model predictive control approach for a sustainable low-carbon district heating system[J]. Energy Conversion and Management,2023,292:117404. [15]ZUO Y,BELLANI S,FERRI M,et al. High-performance alkaline water electrolyzers based on Ru-perturbed Cu nanoplatelets cathode[J]. Nature Communications,2023,14(1):4680 [16]SHANDARR R,TRUDEWIND C A,ZAPP P. Life cycle assessment of hydrogen production via electrolysis - a review[J]. Journal of Cleaner Production,2014,85:151-163. [17]ZHAO C F,YUAN S,CHENG X J,et al. Effect of perfluorosulfonic acid ionomer in anode catalyst layer on proton exchange membrane water electrolyzer performance[J]. Journal of Power Sources,2023,580:233413. [18]DÖNITZ W,ERDLE E. High-temperature electrolysis of water vapor—status of development and perspectives for application[J]. International Journal of Hydrogen Energy,1985,10(5):291-295. [19]BRISSE A,SCHEFOLD J,ZAHID M. High temperature water electrolysis in solid oxide cells[J]. International Journal of Hydrogen Energy,2008,33(20):5375-5382. [20]LIANG M,YU B,WEN M,et al. Preparation of LSM-YSZ composite powder for anode of solid oxide electrolysis cell and its activation mechanism[J]. Journal of Power Sources,2009,190(2):341-345. [21]MOçOTEGUY P,BRISSE A. A review and comprehensive analysis of degradation mechanisms of solid oxide electrolysis cells[J]. International Journal of Hydrogen Energy,2013,38(36):15887-15902. [22]YU H,YANG X J,CHEN H L,et al. Energy storage capacity planning method for improving offshore wind power consumption[J].Sustainability,2022,14(21):14589. [23]LI Z,GUO P,HAN R H,et al. Current status and development trend of wind power generation-based hydrogen production technology[J]. Energy Exploration & Exploitation,2019,37(1):5-25. [24]CHEN H,WU H,KAN T,et al. Low-carbon economic dispatch of integrated energy system containing electric hydrogen production based on VMD-GRU short-term wind power prediction[J]. International Journal of Electrical Power & Energy Systems,2023,154:109420. [25]SUPERCHI F,MATI A,CARCASCI C,et al. Techno-economic analysis of wind-powered green hydrogen production to facilitate the decarbonization of hard-to-abate sectors:A case study on steelmaking[J]. Applied Energy,2023,342:121198. [26]ZHAO Y,SONG H,GUO Y,et al. Super short term combined power prediction for wind power hydrogen production[J]. Energy Reports,2022,8:1387-1395. [27]LU X,DU B,ZHOU S,et al. Optimization of power allocation for wind-hydrogen system multi-stack PEM water electrolyzer considering degradation conditions[J]. International Journal of Hydrogen Energy,2023,48(15):5850-5872. [28]HOU P,ENEVOLDSEN P,EICHMAN J,et al. Optimizing investments in coupled offshore wind -electrolytic hydrogen storage systems in Denmark[J]. Journal of Power Sources,2017,359:186-197. [29]DURAKOVIC G,DEL GRANADO P C,TOMASGARD A. Powering Europe with North Sea offshore wind:The impact of hydrogen investments on grid infrastructure and power prices[J]. Energy,2023,263:125654. [30]DINH V N,LEAHY P,MCKEOGH E,et al. Development of a viability assessment model for hydrogen production from dedicated offshore wind farms[J]. International Journal of Hydrogen Energy,2021,46(48):24620-24631. [31]CHENG C,HUGHES L. The role for offshore wind power in renewable hydrogen production in Australia[J]. Journal of Cleaner Production,2023,391:136223. [32]XIE H,ZHAO Z,LIU T,et al. A membrane-based seawater electrolyser for hydrogen generation[J]. Nature,2022,612(7941):673-678. [33]BOUDRIES R. Analysis of solar hydrogen production in Algeria:Case of an electrolyzer-concentrating photovoltaic system[J]. International Journal of Hydrogen Energy,2013,38(26):11507-11518. [34]BOUDRIES R,DIZENE R. Potentialities of hydrogen production in Algeria[J]. International Journal of Hydrogen Energy,2008,33(17):4476-4487. [35]KUDO A,MISEKI Y. Heterogeneous photocatalyst materials for water splitting[J]. Chemical Society Reviews,2009,38(1):253-278. [36]BHATTACHARYYA R,MISRA A,SANDEEP K C. Photovoltaic solar energy conversion for hydrogen production by alkaline water electrolysis:Conceptual design and analysis[J]. Energy Conversion and Management,2017,133:1-13. [37]HOUAIJIA A,ROEB M,MONNERIE N,et al. Solar power tower as heat and electricity source for a solid oxide electrolyzer:A case study[J]. International Journal of Energy Research,2015,39(8):1120-1130. [38]NAUMANN G,SCHROPP E,STEEGMANN N,et al. Environmental performance of a hybrid solar-hydrogen energy system for buildings[J/OL]. International Journal of Hydrogen Energy,2023.(2023-08-13)[2023-10-25].https//doi.org/10.1016/j.ijhydene.2023.07.208. [39]YANG G,ZHANG H,WANG W,et al. Capacity optimization and economic analysis of PV-hydrogen hybrid systems with physical solar power curve modeling[J]. Energy Conversion and Management,2023,288:117128. [40]NASSER M,HASSAN H. Assessment of standalone streetlighting energy storage systems based on hydrogen of hybrid PV/electrolyzer/fuel cell/ desalination and PV/batteries[J]. Journal of Energy Storage,2023,63:106985. [41]LU Z,ZHU Q,ZHANG W,et al. Economic operation strategy of integrated hydrogen energy system considering the uncertainty of PV power output[J]. Energy Reports,2023,9:463-471. [42]MIRBAGHERI M H,BANIASADI E,GENCELI H. Exploring the performance of an innovative integrated solar tower power plant with hydrogen generation and storage[J]. International Journal of Hydrogen Energy,2023,44(99):39271-39285. [43]NEZHAD Q A,JAFARMADAR S,GENCELI H. Analysis of a novel concentrated solar power and magnetohydrodynamic liquid metal units integrated system with hydrogen production[J]. International Journal of Hydrogen Energy,2023,48(60):22734-22751. [44]YANG H,ZHOU M,WU Z,et al. Exploiting the operational flexibility of a concentrated solar power plant with hydrogen production[J]. Solar Energy,2022,247:158-170. [45]CAI D,BAMISILE O,ADEBAYO V,et al. Integration of wind turbine with heliostat based CSP/CPVT system for hydrogen production and polygeneration:A thermodynamic comparison[J]. International Journal of Hydrogen Energy,2022,47(5):3316-3345. [46]ZHOU P,NAVID I A,MA Y,et al. Solar-to-hydrogen efficiency of more than 9% in photocatalytic water splitting[J]. Nature,2023,613(7942):66-70. [47]ALTAYIB K,DINCER I. Development of an integrated hydropower system with hydrogen and methanol production[J]. Energy,2022,240:122780. [48]ANDRUS S R,DIFFELY R J,ALFORD T L. Theoretical analysis of green hydrogen from hydropower:A case study of the Northwest Columbia River system[J]. International Journal of Hydrogen Energy,2023,48(22):7993-8001. [49]HUANG J,LI W,WU X,et al. A bi-level capacity planning approach of combined hydropower hydrogen system[J]. Journal of Cleaner Production,2021,327:129414. [50]ISLAM A K M K. Hydropower coupled with hydrogen production from wastewater:Integration of micro-hydropower plant (MHP) and microbial electrolysis cell (MEC)[J]. International Journal of Hydrogen Energy,2023.,49(1):1-14. [51]JIN L,ROSSI M,MONFORTI FERRARIO A,et al. Integration of battery and hydrogen energy storage systems with small-scale hydropower plants in off-grid local energy communities[J]. Energy Conversion and Management,2023,286:117019. [52]PUTERA A D,HIDAYAH A N,SUBIANTORO A. Thermo-Economic Analysis of A Geothermal Binary Power Plant in Indonesia—A Pre-Feasibility Case Study of the Wayang Windu Site[J]. Energies,2019,12(22):4269. [53]TEKKANAT B,YUKSEL Y E,OZTURK M. The evaluation of hydrogen production via a geothermal-based multigeneration system with 3E analysis and multi-objective optimization[J]. International Journal of Hydrogen Energy,2023,48(22):8002-8021. [54]SANGESARAKI A G,GHAREHGHANI A,MEHRENJANI J R. 4E analysis and machine learning optimization of a geothermal-based system integrated with ejector refrigeration cycle for efficient hydrogen production and liquefaction[J]. International Journal of Hydrogen Energy,2023,48(82):31875-31904. [55]ZHANG L,QIU Y,CHEN Y,et al. Multi-objective particle swarm optimization applied to a solar-geothermal system for electricity and hydrogen production; Utilization of zeotropic mixtures for performance improvement[J]. Process Safety and Environmental Protection,2023,175:814-833. [56]LIU G,JI D,QIN Y. Geothermal-solar energy system integrated with hydrogen production and utilization modules for power supply-demand balancing[J]. Energy,2023,283:128736. [57]HOSEINZADEH S,GARCIA D A. Techno-economic assessment of hybrid energy flexibility systems for islands' decarbonization:A case study in Italy[J]. Sustainable Energy Technologies and Assessments,2022,51:101929. |