Thermodynamic analysis of a novel two-step high temperature thermo-electrochemical water splitting cycle

Perry, Jonathan; Jones, Timothy W.; Coronado, Juan M.; Donne, Scott W.; Bayon, Alicia

Title: Thermodynamic analysis of a novel two-step high temperature thermo-electrochemical water splitting cycle
Creator: Perry, Jonathan; Jones, Timothy W.; Coronado, Juan M.; Donne, Scott W.; Bayon, Alicia
Relation: Energy Vol. 276, Issue 1 August 2023, no. 127412
Publisher Link: http://dx.doi.org/10.1016/j.energy.2023.127412
Publisher: Elsevier
Resource Type: journal article
Date: 2023
Description: Green hydrogen is a clean fuel aiming to revolutionize the transportation industry in the next decades. It can be produced by several processes with solar electrochemical (EC) and solar thermochemical hydrogen (SCTH) as the most attractive ones. High-temperature solid oxide electrolysis (SOE) is a relatively mature technology; however, these systems suffer low durability due to delamination, build-up of nonconductive phases and separation of metallic electrode contacts. Alternatively, two-step solar thermochemical hydrogen (STCH) exhibits ample durability and benefit from cheaper thermal energy, although solar-to-hydrogen efficiencies remain low. Herein, a novel electrochemically assisted solar thermochemical hydrogen production process (EC-STCH) is proposed, presenting a fundamental thermodynamic analysis of this novel route and a comparison with conventional SCTH and SOE, assuming a fixed H2O-to-H2 conversion of 10% and 50%. The thermodynamic model is based on fundamental thermodynamic principles and demonstrates that for materials which require a ΔT > 500 °C to conduct both reactions in STCH, could operate at lower temperatures and ΔT = 0 °C. Reaction conditions were evaluated showing that it may also be possible to increase the oxygen partial pressure while still achieving high fuel conversion, which would not be possible operating under the conventional SOE and STCH conditions.
Subject: solar energy; thermochemical cycles; hydrogen production; thermodynamic properties; water splitting; solid-oxide electrolysis; SDG 7; Sustainable Development Goals
Identifier: http://hdl.handle.net/1959.13/1490464
Identifier: uon:52920
Identifier: ISSN:0360-5442
Rights: x
Language: eng
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