Abstract
Direct carbon fuel cell (DCFC) is a promising technology with high energy efficiency and abundant fuel. To date, a variety of DCFC configurations have been investigated, with molten hydroxide, molten carbonate or oxides being used as the electrolyte. Recently, there has been particular interest in DCFC with molten carbonate involved. The molten carbonate is either an electrolyte or a catalyst in different cell structures. In this review, we consider carbonate as the clue to discuss the function of carbonate in DCFCs, and start the paper by outlining the developments in terms of molten carbonate (MC)-based DCFC and its electrochemical oxidation processes. Thereafter, the composite electrolyte merging solid carbonate and mixed ionic–electronic conductors (MIEC) are discussed. Hybrid DCFC (HDCFCs ) combining molten carbonate and solid oxide fuel cell (SOFC) are also touched on. The primary function of carbonate (i.e., facilitating ion transfer and expanding the triple-phase boundaries) in these systems, is then discussed in detail. Finally, some issues are identified and a future outlook outlined, including a corrosion attack of cell components, reactions using inorganic salt from fuel ash, and wetting with carbon fuels.
Highlights
Fuel cells (FCs) offer an environmentally friendly and highly efficient approach to energy-conversion technology for power generation
Rady et al [51] reviewed the performance of various fuels used in molten carbonate fuel cell (MCFC) and solid oxide fuel cell (SOFC), and Zhou et al [52] published a review paper that discussed the anode used in Direct carbon fuel cell (DCFC)
Jiang et al [53] presented an overview of the impact of different parameters on the resistance and power output and the electrochemical behavior of DCFCs, and summarized the challenges associated with developing DCFCs
Summary
Fuel cells (FCs) offer an environmentally friendly and highly efficient approach to energy-conversion technology for power generation. This approach has been intensively investigated for over a hundred years, since Grove et al [1] developed the first FC in 1839. The first DCFC was reported by Becquerel [5] in the middle of the nineteenth century; the configuration was a carbon rod in a K NO3 solution inside a platinum container. Later research reported that gases from solid carbon pyrolysis are involved in the electrochemical
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