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Energies 2020, 13, 5859 21 of 23 64. Setoodeh Jahromy, S.; Jordan, C.; Azam, M.; Werner, A.; Harasek, M.; Winter, F. Fly Ash from Municipal Solid Waste Incineration as a Potential Thermochemical Energy Storage Material. Energy Fuels 2019, 33, 5810–5819. [CrossRef] 65. Setoodeh Jahromy, S.; Azam, M.; Huber, F.; Jordan, C.; Wesenauer, F.; Huber, C.; Naghdi, S.; Schwendtner, K.; Neuwirth, E.; Laminger, T.; et al. Comparing Fly Ash Samples from Different Types of Incinerators for Their Potential as Storage Materials for Thermochemical Energy and CO2. Materials 2019, 12, 3358. [CrossRef] 66. Valverde, J.M.; Miranda-Pizarro, J.; Perejón, A.; Sánchez-Jiménez, P.E.; Pérez-Maqueda, L.A. Calcium-Looping performance of steel and blast furnace slags for thermochemical energy storage in concentrated solar power plants. J. CO2 Util. 2017, 22, 143–154. [CrossRef] 67. Bagherisereshki, E.; Tran, J.; Lei, F.; AuYeung, N. Investigation into SrO/SrCO3 for high temperature thermochemical energy storage. Sol. Energy 2018, 160, 85–93. [CrossRef] 68. Meroueh, L.; Yenduru, K.; Dasgupta, A.; Jiang, D.; AuYeung, N. Energy storage based on SrCO3 and Sorbents—A probabilistic analysis towards realizing solar thermochemical power plants. Renew. Energy 2019, 133, 770–786. [CrossRef] 69. Zare Ghorbaei, S.; Ale Ebrahim, H. Carbonation reaction of strontium oxide for thermochemical energy storage and CO2 removal applications: Kinetic study and reactor performance prediction. Appl. Energy 2020, 277, 115604. [CrossRef] 70. Ammendola, P.; Raganati, F.; Miccio, F.; Murri, A.N.; Landi, E. Insights into utilization of strontium carbonate for thermochemical energy storage. Renew. Energy 2020, 157, 769–781. [CrossRef] 71. Gigantino, M.; Kiwic, D.; Steinfeld, A. Thermochemical energy storage via isothermal carbonation-calcination cycles of MgO-stabilized SrO in the range of 1000–1100 ◦C. Sol. Energy 2019, 188, 720–729. [CrossRef] 72. Møller, K.T.; Williamson, K.; Buckley, C.E.; Paskevicius, M. Thermochemical energy storage properties of a barium based reactive carbonate composite. J. Mater. Chem. A 2020, 8, 10935–10942. [CrossRef] 73. Takasu, H.; Ryu, J.; Kato, Y. Application of lithium orthosilicate for high-temperature thermochemical energy storage. Appl. Energy 2017, 193, 74–83. [CrossRef] 74. Gravogl, G.; Knoll, C.; Artner, W.; Welch, J.M.; Eitenberger, E.; Friedbacher, G.; Harasek, M.; Hradil, K.; Werner, A.; Weinberger, P.; et al. Pressure effects on the carbonation of MeO (Me = Co, Mn, Pb, Zn) for thermochemical energy storage. Appl. Energy 2019, 252, 113451. [CrossRef] 75. Silakhori, M.; Jafarian, M.; Arjomandi, M.; Nathan, G.J. Thermogravimetric analysis of Cu, Mn, Co, and Pb oxides for thermochemical energy storage. J. Energy Storage 2019, 23, 138–147. [CrossRef] 76. Setoodeh Jahromy, S.; Birkelbach, F.; Jordan, C.; Huber, C.; Harasek, M.; Werner, A.; Winter, F. Impact of Partial Pressure, Conversion, and Temperature on the Oxidation Reaction Kinetics of Cu2O to CuO in Thermochemical Energy Storage. Energies 2019, 12, 508. [CrossRef] 77. Silakhori, M.; Jafarian, M.; Arjomandi, M.; Nathan, G.J. Comparing the thermodynamic potential of alternative liquid metal oxides for the storage of solar thermal energy. Sol. Energy 2017, 157, 251–258. [CrossRef] 78. Deutsch, M.; Horvath, F.; Knoll, C.; Lager, D.; Gierl-Mayer, C.; Weinberger, P.; Winter, F. High-Temperature Energy Storage: Kinetic Investigations of the CuO/Cu2O Reaction Cycle. Energy Fuels 2017, 31, 2324–2334. [CrossRef] 79. Bush, H.E.; Loutzenhiser, P.G. Solar electricity via an Air Brayton cycle with an integrated two-step thermochemical cycle for heat storage based on Fe2O3/Fe3O4 redox reactions: Thermodynamic and kinetic analyses. Sol. Energy 2018, 174, 617–627. [CrossRef] 80. Carrillo, A.J.; Sastre, D.; Serrano, D.P.; Pizarro, P.; Coronado, J.M. Revisiting the BaO2/BaO redox cycle for solar thermochemical energy storage. Phys. Chem. Chem. Phys. 2016, 18, 8039–8048. [CrossRef] 81. André, L.; Abanades, S.; Cassayre, L. Experimental Investigation of Co–Cu, Mn–Co, and Mn–Cu Redox Materials Applied to Solar Thermochemical Energy Storage. ACS Appl. Energy Mater. 2018, 1, 3385–3395. [CrossRef] 82. Block, T.; Schmücker, M. Metal oxides for thermochemical energy storage: A comparison of several metal oxide systems. Sol. Energy 2016, 126, 195–207. [CrossRef] 83. Carrillo, A.J.; Serrano, D.P.; Pizarro, P.; Coronado, J.M. Manganese oxide-based thermochemical energy storage: Modulating temperatures of redox cycles by Fe–Cu co-doping. J. Energy Storage 2016, 5, 169–176. [CrossRef]PDF Image | Hi Temp Thermochemical Energy Storage via Solid Gas Reactions
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