Medium-temperature sodium-bromine and sodium-iodine battery systems operating at 3.5 V and 3.0 V, respectively, are presented. The rechargeable molten-sodium systems work at approx. 100 degrees C and use aqueous bromine/bromide or iodine/iodide solutions as catholyte and sodium-ion conductive NaSICON (Na3Zr2Si2.3P0.7O11.85) as solid electrolyte. The free halogen, which is formed upon charge, is complexed as highly soluble tribromide and triiodide, respectively. These systems can work in both, static and redoxflow setup, respectively, and aim at stationary energy storage applications. The sodium-halogen batteries were shown to run with high coulombic efficiency over several hundred hours. Long-term stability of the NaSICON ceramic material in contact with aqueous electrolytes, however, is still a concern. The sodiumbromine system suffers from a considerable bromine vapour pressure of the tribromide, whereas the sodium-iodine system was shown to operate in a stable manner with a catholyte allowing for a high total iodine concentration (>= 2.0 M). Catholyte concentrations up to 2.75 M total iodine in redox-flow setup and up 3.7 M in static setup are possible without iodine precipitation and correspond to specific energies of 198 Wh kg (1) and 228 Wh kg (1), respectively, on total active material level. (C) 2017 Elsevier Ltd. All rights reserved.