@article {1077, title = {Solar Thermochemical Hydrogen (STCH) Processes}, journal = {The Electrochemical Society Interface}, volume = {27}, year = {2018}, pages = {53-56}, issn = {1064-8208, 1944-8783}, doi = {10.1149/2.F05181if}, url = {http://interface.ecsdl.org/lookup/doi/10.1149/2.F05181if}, author = {Maximilian B. Gorensek and Claudio Corgnale and John A. Staser and John W. Weidner} } @article {801, title = {Characterizing Voltage Losses in an SO2 Depolarized Electrolyzer Using Sulfonated Polybenzimidazole Membranes}, journal = {Journal of The Electrochemical Society}, volume = {164}, year = {2017}, note = {{\textquoteright}doi: 10.1021/acsenergylett.0c01132\n - I.Am.Hydrogen{\textquoteright} {\textquoteright}\n - jyoungstrom{\textquoteright} {\textquoteright}Jason thinks this is great.\n~\n - jyoungstrom{\textquoteright} {\textquoteright}\n - estechel{\textquoteright} }, pages = {F1591-F1595}, abstract = {Published on January 1st, 2017. The hybrid sulfur cycle has been investigated as a means to produce CO2-free hydrogen efficiently on a large scale through the decomposition of H2SO4 to SO2, O2, and H2O, and then electrochemically oxidizing SO2 back to H2SO4 with the cogeneration of H2. The net effect is the production of hydrogen and oxygen from water. Recently, sulfonated polybenzimidazoles (s-PBI) have been investigated as a replacement for Nafion due to the ability to offer increased process efficiency through the generation of higher acid concentrations at lower potentials. Here, we measure the acid concentrations and individual potential contributions toward the overall operating voltage seen in the SO2-depolarized-electrolyzer. We then determine model parameters necessary to predict voltage losses in a cell over a wide range of operating temperatures, pressures, currents and reactant flow rates.}, issn = {0013-4651, 1945-7111}, doi = {10.1149/2.1061714jes}, url = {http://jes.ecsdl.org/content/164/14/F1591}, author = {Taylor R. Garrick and Cody H. Wilkins and Andrew T. Pingitore and Jacob Mehlhoff and Alex Gulledge and Brian C. Benicewicz and John W. Weidner} }