The electrochemistry of unbuffered and buffered neutral AlCl3-EMIC-MCl (EMIC = 1-ethyl-3-methylimidazolium chloride and MCl = LiCl, NaCl or KCl) room-temperature molten salts was studied at graphitic and nongraphitic electrodes. In the case of the unbuffered 1:1 AlCl3:EMIC molten salt, the organic cation reductive intercalation at about -1.6V and the AlCl4- anion oxidative intercalation at about +1.8 V were evaluated at porous graphite electrodes. It was determined that the instability of the organic cation in the graphite lattice limits the performance of a dual intercalating molten electrolyte (DIME) cell based on this electrolyte. In buffered neutral 1.1:1.0:0.1 AlCl3:EMIC:MCl (MCl = LiCl, NaCl and KCl) molten salts, the organic cation was intercalated into porous and nonporous graphite electrodes with similar cycling efficiencies as the unbuffered 1:1 melt; however, additional nonintercalating processes were also found to occur between -1 and -1.6V in the LiCl and NaCl systems. A black electrodeposit, formed at -1.4V in the LiCl buffered neutral melt, was analysed with X-ray photoelectron spectroscopy and X-ray diffraction and was found to be composed of LiCl, metallic phases containing lithium and aluminium, and an alumina phase formed from reaction with the atmosphere. A similar film appears to form in the NaCl buffered neutral melt, but at a much slower rate. These films are believed to form by reduction of the AlCl4- anion, a process promoted by decreasing the ionic radius of the alkali metal cation in the molten salt. The partially insulating films may limit the usefulness of the LiCl and NaCl buffered neutral melts as electrolytes for rechargeable graphite intercalation anodes and may interfere with other electrochemical processes occurring negative of -1V.