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Fe─N─C Electrocatalyst for Enhancing Fe(II)/Fe(III) Redox Kinetics in Thermo‐Electrochemical Cells

Sang‐Mun Jung, SeungYeon Kang, Byung‐Jo Lee, Jinhyeon Lee, Jaesub Kwon, Dongwook Lee, Yong‐Tae Kim

2023Advanced Functional Materials21 citationsDOIOpen Access PDF

Abstract

Abstract Harvesting low‐grade waste heat, which constitutes 60% of the overall waste heat, is key to halting climate change. Electrochemical waste‐heat harvesting has recently drawn attention to practical low‐grade waste‐heat harvesting. In this study, a power density maximization strategy is presented in scalable and cost‐effective aqueous redox couple‐based thermo‐electrochemical cells (TECs). The n‐type feature of the water‐soluble Fe 2+/3+ redox couple is essential for constructing the TEC p–n leg device; however, it has not been investigated much so far. The modulation of the chaotropicity of counteranions enhances the absolute value of the Seebeck coefficient for the Fe 2+/3+ redox couple with an inner‐sphere reaction mechanism because of the greater structural disorder in the solvation shell. Moreover, the use of a cost‐effective Fe─N─C electrocatalyst shows redox kinetics and a power density comparable to those of state‐of‐the‐art Pt electrodes, economically compensating for the sluggish charge‐transfer kinetics of the inner‐sphere redox mechanism. The Fe─N─C ‐based TEC device exhibits 1.73 W m −2 of power density at 0.1 $ W −1 of cost per power, which is 1.24% with respect to the Carnot efficiency, exceeding 0.23–0.53% compared to those reported for previous Pt‐based TEC devices with the same redox chemistry.

Topics & Concepts

RedoxElectrocatalystElectrochemistryMaterials scienceElectrochemical kineticsChemical engineeringPower densityKineticsThermodynamicsElectrodeChemistryPhysical chemistryPower (physics)PhysicsMetallurgyQuantum mechanicsEngineeringAdvanced Thermoelectric Materials and DevicesAdvanced battery technologies researchElectrocatalysts for Energy Conversion
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