碳中和背景下生物质能源和绿色氢能在大规模储能中的作用

[1]	Gilles D.Biomass, a massively available and major source of energy, an unsustainable use [Internet]. Grenoble: Encyclopédie de l'énergie Grenoble; 2022 Mar 7 [cited 2022 Dec 26]. Available from: https://www.encyclopedie-energie.org/en/biomass-major-source-energy-unsustainable-use/.
[2]	The World Counts. Global energy consumption only going up [Internet]. Copenhagen: The World Counts; [cited 2022 Dec 26]. Available from: https://www.theworldcounts.com/challenges/climate-change/energy/global-energy-consumption.
[3]	IEA Bioenergy.Carbon neutrality [Internet]. Paris: IEA Bioenergy; [cited 2022 Dec 26]. Available from: https://www.ieabioenergy.com/iea-publications/faq/woodybiomass/carbon-neutrality/.
[4]	D. Iluz, S. Abu-Ghosh. A novel photobioreactor creating fluctuating light from solar energy for a higher light-to-biomass conversion efficiency. Energ Conver Manage, 126 ( 2016), pp. 767-773
[5]	D. Parlevliet, N.R. Moheimani. Efficient conversion of solar energy to biomass and electricity. Aquat Biosyst, 10 (1) ( 2014), p. 4. DOI: 10.1186/2046-9063-10-4
[6]	R.J. Macías, C. Ceballos, J. Ordonez-Loza, M. Ortiz, C.A. G’omez, F. Chejne, et al.. Evaluation of the performance of a solar photovoltaic-biomass gasifier system as electricity supplier. Energy, 260 ( 2022), Article 125046
[7]	O. Oner, I. Dincer. A unique solar and biomass-based system for integrated production of electricity, heat, freshwater, hydrogen and ethanol. Energ Conver Manage, 269 ( 2022), Article 116115
[8]	J.L. Ling, E.S. Go, Y.K. Park, S.H. Lee. Recent advances of hybrid solar-biomass thermo-chemical conversion systems. Chemosphere, 290 ( 2022), Article 133245
[9]	International Energy Agency (IEA). World energy outlook 2022. Report. Paris: IEA; 2022.
[10]	H. Chen, T.N. Cong, W. Yang, C. Tan, Y. Li, Y. Ding. Progress in electrical energy storage system: a critical review. Prog Nat Sci, 19 (3) ( 2009), pp. 291-312
[11]	S. Hameer, J.L. van Niekerk. A review of large-scale electrical energy storage. Int J Energy Res, 39 (9) ( 2015), pp. 1179-1195. DOI: 10.1002/er.3294
[12]	U. Eberle, M. Felderhoff, F. Schüth. Chemical and physical solutions for hydrogen storage. Angew Chem Int Ed, 48 (36) ( 2009), pp. 6608-6630. DOI: 10.1002/anie.200806293
[13]	F. Gutiérrez-Martín, L.M. Rodriguez-Anton. Power-to-SNG technologies by hydrogenation of CO₂ and biomass resources: a comparative chemical engineering process analysis. Int J Hydrogen Energy, 44 (25) ( 2019), pp. 12544-12553
[14]	K. Müller, M. Städter, F. Rachow, D. Hoffmannbeck, D. Schmeißer. Sabatier-based CO₂-methanation by catalytic conversion. Environ Earth Sci, 70 (8) ( 2013), pp. 3771-3778. DOI: 10.1007/s12665-013-2609-3
[15]	L. Jürgensen, E.A. Ehimen, J. Born, J.B. Holm-Nielsen. Utilization of surplus electricity from wind power for dynamic biogas upgrading: northern Germany case study. Biomass Bioenergy, 66 ( 2014), pp. 126-132
[16]	L.R. Clausen, N. Houbak, B. Elmegaard. Technoeconomic analysis of a methanol plant based on gasification of biomass and electrolysis of water. Energy, 35 (5) ( 2010), pp. 2338-2347
[17]	EUROCONTROL. European aviation in 2040:challenges of growth. Report. Brussels: EUROCONTROL; 2018.
[18]	T.J. Morgan, A. Youkhana, S.Q. Turn, R. Ogoshi, M. Garcia-Péerez. Review of biomass resources and conversion technologies for alternative jet fuel production in Hawai’i and tropical regions. Energy Fuels, 33 (4) ( 2019), pp. 2699-12662. DOI: 10.1021/acs.energyfuels.8b03001
[19]	International Energy Agency (IEA).What does net-zero emissions by 2050 mean for bioenergy and land use? [Internet]. Paris: IEA; 2021 May 31 [cited 2022 Dec 26]. Available from: https://www.iea.org/articles/what-does-net-zero-emissions-by-2050-mean-for-bioenergy-and-land-use.
[20]	Government of Canada. Hydrogen strategy for Canada—seizing the opportunities for hydrogen: a call to action. Canada’s Minister of Natural Resources, Ottawa ( 2020)