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Redox cycles with doped calcium manganites for thermochemical energy storage to 1000 °C

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  • Imponenti, Luca
  • Albrecht, Kevin J.
  • Kharait, Rounak
  • Sanders, Michael D.
  • Jackson, Gregory S.

Abstract

Redox cycles of doped calcium manganite perovskites (CaMnO3−δ) are studied for cost-effective thermochemical energy storage at temperatures up to 1000 °C for concentrating solar power and other applications. If the thermodynamics and kinetics for heat-driven reduction can be tailored for high temperatures and industrially accessible low O2 partial pressures (PO2⩾10-4 bar), perovskite redox cycles can offer high specific energy storage at temperatures much higher than state-of-the-art molten-salt subsystems. To this end, a range of A-site and B-site doped CaMnO3−δ were screened for their reducibility at 900 °C and PO2≈10-4 bar via thermogravimetric analysis. For compositions with high reducibility, notably A-site doped Ca1−xSrxMnO3−δ (x=0.05 and 0.10) and B-site doped CaCryMn1−yO3−δ (y=0.05 and 0.10), oxygen non-stoichiometry δ with respect to temperature and PO2 were measured and used to fit thermodynamic parameters of a two-reaction, point-defect model of the redox process for the two prominent crystalline phases (orthorhombic and cubic) that the perovskites occupy during the cycle. The fits compare favorably to differential scanning calorimetry measurements with the magnitude of the overall reduction enthalpies decreasing as the degree of reduction increases and the perovskites shift from orthorhombic to cubic crystalline phases. Based on thermodynamic limits, redox cycles of both Ca1−xSrxMnO3−δ compositions between air at 500 °C and PO2≈10-4 bar at 900 °C can store and release up to ≈700 kJ kg−1 with over 50% of the total energy stored as chemical energy. This is approximately 140 kJ kg−1 more chemical energy than the thermodynamic limits for CaCryMn1−yO3−δ compositions under the same cycle conditions. Approaching these thermodynamic limits for the specific energy storage of these redox cycles in a concentrating solar plant requires fast kinetics for perovskite reduction in the solar receiver and for reoxidation in the heat recovery reactor. Isothermal packed-bed redox cycling experiments of Ca1−xSrxMnO3−δ and CaCryMn1−yO3−δ compositions at temperatures up to 1000 °C show that reoxidation is fast compared to reduction. Thus, specific thermochemical energy storage is limited by residence times available for high-temperature reduction. The Sr-doped compositions approach higher fractions (≈90% or more) of the specific energy storage equilibrium limit after 300 s of reduction in the packed bed configuration above 800 °C and completely reoxidize in ⩽20 s in air. Non-isothermal cycling with heating from 500 °C to 900 °C in low PO2≈10-4 bar and subsequent reoxidation during cooling in air back to 500 °C demonstrate excellent chemical stability over 1000 cycles for all doped CaMnO3−δ compositions tested. The results suggest that these redox cycles may offer a viable energy storage subsystem with long-term stability for future concentrating solar plants and other high-temperature energy storage applications.

Suggested Citation

  • Imponenti, Luca & Albrecht, Kevin J. & Kharait, Rounak & Sanders, Michael D. & Jackson, Gregory S., 2018. "Redox cycles with doped calcium manganites for thermochemical energy storage to 1000 °C," Applied Energy, Elsevier, vol. 230(C), pages 1-18.
    • Handle: RePEc:eee:appene:v:230:y:2018:i:c:p:1-18
    DOI: 10.1016/j.apenergy.2018.08.044
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    1. Schmitz, Matthias & Linderholm, Carl Johan, 2016. "Performance of calcium manganate as oxygen carrier in chemical looping combustion of biochar in a 10kW pilot," Applied Energy, Elsevier, vol. 169(C), pages 729-737.
    2. Galinsky, Nathan & Sendi, Marwan & Bowers, Lindsay & Li, Fanxing, 2016. "CaMn1−xBxO3−δ (B=Al, V, Fe, Co, and Ni) perovskite based oxygen carriers for chemical looping with oxygen uncoupling (CLOU)," Applied Energy, Elsevier, vol. 174(C), pages 80-87.
    3. Charvin, Patrice & Abanades, Stéphane & Flamant, Gilles & Lemort, Florent, 2007. "Two-step water splitting thermochemical cycle based on iron oxide redox pair for solar hydrogen production," Energy, Elsevier, vol. 32(7), pages 1124-1133.
    4. Evans, Annette & Strezov, Vladimir & Evans, Tim J., 2012. "Assessment of utility energy storage options for increased renewable energy penetration," Renewable and Sustainable Energy Reviews, Elsevier, vol. 16(6), pages 4141-4147.
    5. Lapp, J. & Davidson, J.H. & Lipiński, W., 2012. "Efficiency of two-step solar thermochemical non-stoichiometric redox cycles with heat recovery," Energy, Elsevier, vol. 37(1), pages 591-600.
    6. Tescari, S. & Singh, A. & Agrafiotis, C. & de Oliveira, L. & Breuer, S. & Schlögl-Knothe, B. & Roeb, M. & Sattler, C., 2017. "Experimental evaluation of a pilot-scale thermochemical storage system for a concentrated solar power plant," Applied Energy, Elsevier, vol. 189(C), pages 66-75.
    7. Vignarooban, K. & Xu, Xinhai & Arvay, A. & Hsu, K. & Kannan, A.M., 2015. "Heat transfer fluids for concentrating solar power systems – A review," Applied Energy, Elsevier, vol. 146(C), pages 383-396.
    8. Galinsky, Nathan & Mishra, Amit & Zhang, Jia & Li, Fanxing, 2015. "Ca1−xAxMnO3 (A=Sr and Ba) perovskite based oxygen carriers for chemical looping with oxygen uncoupling (CLOU)," Applied Energy, Elsevier, vol. 157(C), pages 358-367.
    9. Chacartegui, R. & Alovisio, A. & Ortiz, C. & Valverde, J.M. & Verda, V. & Becerra, J.A., 2016. "Thermochemical energy storage of concentrated solar power by integration of the calcium looping process and a CO2 power cycle," Applied Energy, Elsevier, vol. 173(C), pages 589-605.
    10. Görke, R.H. & Hu, W. & Dunstan, M.T. & Dennis, J.S. & Scott, S.A., 2018. "Exploration of the material property space for chemical looping air separation applied to carbon capture and storage," Applied Energy, Elsevier, vol. 212(C), pages 478-488.
    11. Liu, Ming & Steven Tay, N.H. & Bell, Stuart & Belusko, Martin & Jacob, Rhys & Will, Geoffrey & Saman, Wasim & Bruno, Frank, 2016. "Review on concentrating solar power plants and new developments in high temperature thermal energy storage technologies," Renewable and Sustainable Energy Reviews, Elsevier, vol. 53(C), pages 1411-1432.
    12. Albrecht, Kevin J. & Jackson, Gregory S. & Braun, Robert J., 2016. "Thermodynamically consistent modeling of redox-stable perovskite oxides for thermochemical energy conversion and storage," Applied Energy, Elsevier, vol. 165(C), pages 285-296.
    13. Bauer, Thomas & Pfleger, Nicole & Breidenbach, Nils & Eck, Markus & Laing, Doerte & Kaesche, Stefanie, 2013. "Material aspects of Solar Salt for sensible heat storage," Applied Energy, Elsevier, vol. 111(C), pages 1114-1119.
    14. Anderson, Ryan & Shiri, Samira & Bindra, Hitesh & Morris, Jeffrey F., 2014. "Experimental results and modeling of energy storage and recovery in a packed bed of alumina particles," Applied Energy, Elsevier, vol. 119(C), pages 521-529.
    15. Prieto, Cristina & Osuna, Rafael & Fernández, A. Inés & Cabeza, Luisa F., 2016. "Molten salt facilities, lessons learnt at pilot plant scale to guarantee commercial plants; heat losses evaluation and correction," Renewable Energy, Elsevier, vol. 94(C), pages 175-185.
    16. Cabeza, Luisa F. & Solé, Aran & Fontanet, Xavier & Barreneche, Camila & Jové, Aleix & Gallas, Manuel & Prieto, Cristina & Fernández, A. Inés, 2017. "Thermochemical energy storage by consecutive reactions for higher efficient concentrated solar power plants (CSP): Proof of concept," Applied Energy, Elsevier, vol. 185(P1), pages 836-845.
    17. Denholm, Paul & Hand, Maureen, 2011. "Grid flexibility and storage required to achieve very high penetration of variable renewable electricity," Energy Policy, Elsevier, vol. 39(3), pages 1817-1830, March.
    18. Pelay, Ugo & Luo, Lingai & Fan, Yilin & Stitou, Driss & Rood, Mark, 2017. "Thermal energy storage systems for concentrated solar power plants," Renewable and Sustainable Energy Reviews, Elsevier, vol. 79(C), pages 82-100.
    19. Iverson, Brian D. & Conboy, Thomas M. & Pasch, James J. & Kruizenga, Alan M., 2013. "Supercritical CO2 Brayton cycles for solar-thermal energy," Applied Energy, Elsevier, vol. 111(C), pages 957-970.
    20. Lin, Meng & Haussener, Sophia, 2015. "Solar fuel processing efficiency for ceria redox cycling using alternative oxygen partial pressure reduction methods," Energy, Elsevier, vol. 88(C), pages 667-679.
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    2. Lei, Qi & Si, Qianli & Zhang, Ji & Jiang, Yifeng & Hu, Long & Qiao, Liang & Zu, Xiaotao & Xiao, Gang & Yang, Jack & Li, Sean, 2022. "Redox cycle of calcium manganite for high temperature solar thermochemical storage systems," Applied Energy, Elsevier, vol. 305(C).
    3. Nicole Carina Preisner & Marc Linder, 2020. "A Moving Bed Reactor for Thermochemical Energy Storage Based on Metal Oxides," Energies, MDPI, vol. 13(5), pages 1-20, March.
    4. Selvan Bellan & Tatsuya Kodama & Nobuyuki Gokon & Koji Matsubara, 2022. "A review on high‐temperature thermochemical heat storage: Particle reactors and materials based on solid–gas reactions," Wiley Interdisciplinary Reviews: Energy and Environment, Wiley Blackwell, vol. 11(5), September.
    5. Han, Xiangyu & Wang, Liang & Ling, Haoshu & Ge, Zhiwei & Lin, Xipeng & Dai, Xingjian & Chen, Haisheng, 2022. "Critical review of thermochemical energy storage systems based on cobalt, manganese, and copper oxides," Renewable and Sustainable Energy Reviews, Elsevier, vol. 158(C).

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