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Roman's paper uses Grampps thesis (cite me) and the approach to modeling the reactions is taken from Dan Keene \cite{Keene_2013}  \item  The requisite papers by Chueh and Haile that motivate the use of ceria for redox: \cite{Chueh_2010} \cite{Chueh_2010a}  W. C. Chueh, S. M. Haile. A thermochemical study of ceria: exploiting an old material for new modes of energy conversion and CO2 mitigation. Philosophical Transactions of the Royal Society A: Mathematical Physical and Engineering Sciences 368, 3269–3294 (2010). Link  W C Chueh, C Falter, M Abbott, D Scipio, P Furler, S M Haile, A Steinfeld. High-flux solar-driven thermochemical dissociation of CO2 and H2O using nonstoichiometric ceria. Science 330, 1797–1801 (2010).  \item   These peoples modeled an entire reactor setup of ceria in a falling particle configuration: \cite{Oles_2015}. Not surprisingly, they found that the efficiency was low because the ceria particles do not absorb well. They go on to say that they must instead reflect well, which is not really so---the radiation goes right through!  Andrew S. Oles, Gregory S. Jackson. Modeling of a concentrated-solar falling-particle receiver for ceria reduction. Solar Energy 122, 126–147 (2015).