@inproceedings{K{\"o}lbachH{\"o}hnBarryetal.2022, author = {K{\"o}lbach, Moritz and H{\"o}hn, Oliver and Barry, James and Finkbeiner, Manuel and Rehfeld, Kira and May, Matthias M.}, title = {Climatic response of thermally coupled solar water splitting in Antarctica}, booktitle = {EGU General Assembly 2022, Vienna, Austria, 23-27 May 2022}, doi = {10.5194/egusphere-egu22-11608}, institution = {Internationales Zentrum f{\"u}r Nachhaltige Entwicklung (IZNE)}, pages = {11608}, year = {2022}, abstract = {Hydrogen is a versatile energy carrier. When produced with renewable energy by water splitting, it is a carbon neutral alternative to fossil fuels. The industrialization process of this technology is currently dominated by electrolyzers powered by solar or wind energy. For small scale applications, however, more integrated device designs for water splitting using solar energy might optimize hydrogen production due to lower balance of system costs and a smarter thermal management. Such devices offer the opportunity to thermally couple the solar cell and the electrochemical compartment. In this way, heat losses in the absorber can be turned into an efficiency boost for the device via simultaneously enhancing the catalytic performance of the water splitting reactions, cooling the absorber, and decreasing the ohmic losses.[1,2] However,integrated devices (sometimes also referred to as "artificial leaves"), currently suffer from a lower technology readiness level (TRL) than the completely decoupled approach.}, language = {en} }