Lowering the Temperature of Solid Oxide Electrochemical Cells Using Triple-Doped Bismuth Oxides

Hyeongmin Yu; Incheol Jeong; Seungsoo Jang; Doyeub Kim; Ha Ni Im; Chan Woo Lee; Eric D. Wachsman; Kang Taek Lee

doi:10.1002/adma.202306205

Lowering the Temperature of Solid Oxide Electrochemical Cells Using Triple-Doped Bismuth Oxides

Hyeongmin Yu
, Incheol Jeong
, Seungsoo Jang
, Doyeub Kim
, Ha Ni Im
, Chan Woo Lee
, Eric D. Wachsman
, Kang Taek Lee

Department of Energy and Materials Engineering

Korea Advanced Institute of Science and Technology
University of Maryland, College Park

Research output: Contribution to journal › Article › peer-review

37 Scopus citations

Abstract

Despite the great potential of solid oxide electrochemical cells (SOCs) as highly efficient energy conversion devices, the undesirable high operating temperature limits their wider applicability. Herein, a novel approach to developing high-performance low-temperature SOCs (LT-SOCs) is presented through the use of an Er, Y, and Zr triple-doped bismuth oxide (EYZB). This study demonstrates that EYZB exhibits > 147 times higher ionic conductivity of 0.44 S cm⁻¹ at 600 °C compared to commercial Y-stabilized zirconia electrolyte with excellent stability over 1000 h. By rationally incorporating EYZB in composite electrodes and bilayer electrolytes, the zirconia-based electrolyte LT-SOC achieves the unprecedentedly high performance of 3.45 and 2.02 W cm⁻² in the fuel cell mode and 2.08 and 0.95 A cm⁻² in the electrolysis cell mode at 700 °C and 600 °C, respectively. Further, a distinctive microstructural feature of EYZB that largely extends triple phase boundary at the interface is revealed through digital twinning. This work provides insights for developing high-performance LT-SOCs.

Original language	English
Article number	2306205
Journal	Advanced Materials
Volume	36
Issue number	5
DOIs	https://doi.org/10.1002/adma.202306205
State	Published - 1 Feb 2024

Keywords

bismuth oxides
digital twinning
electrolysis cells
first-principles calculations
fuel cells

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title = "Lowering the Temperature of Solid Oxide Electrochemical Cells Using Triple-Doped Bismuth Oxides",

abstract = "Despite the great potential of solid oxide electrochemical cells (SOCs) as highly efficient energy conversion devices, the undesirable high operating temperature limits their wider applicability. Herein, a novel approach to developing high-performance low-temperature SOCs (LT-SOCs) is presented through the use of an Er, Y, and Zr triple-doped bismuth oxide (EYZB). This study demonstrates that EYZB exhibits > 147 times higher ionic conductivity of 0.44 S cm−1 at 600 °C compared to commercial Y-stabilized zirconia electrolyte with excellent stability over 1000 h. By rationally incorporating EYZB in composite electrodes and bilayer electrolytes, the zirconia-based electrolyte LT-SOC achieves the unprecedentedly high performance of 3.45 and 2.02 W cm−2 in the fuel cell mode and 2.08 and 0.95 A cm−2 in the electrolysis cell mode at 700 °C and 600 °C, respectively. Further, a distinctive microstructural feature of EYZB that largely extends triple phase boundary at the interface is revealed through digital twinning. This work provides insights for developing high-performance LT-SOCs.",

keywords = "bismuth oxides, digital twinning, electrolysis cells, first-principles calculations, fuel cells",

author = "Hyeongmin Yu and Incheol Jeong and Seungsoo Jang and Doyeub Kim and Im, \{Ha Ni\} and Lee, \{Chan Woo\} and Wachsman, \{Eric D.\} and Lee, \{Kang Taek\}",

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AU - Yu, Hyeongmin

AU - Jeong, Incheol

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AU - Kim, Doyeub

AU - Im, Ha Ni

AU - Lee, Chan Woo

AU - Wachsman, Eric D.

AU - Lee, Kang Taek

PY - 2024/2/1

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N2 - Despite the great potential of solid oxide electrochemical cells (SOCs) as highly efficient energy conversion devices, the undesirable high operating temperature limits their wider applicability. Herein, a novel approach to developing high-performance low-temperature SOCs (LT-SOCs) is presented through the use of an Er, Y, and Zr triple-doped bismuth oxide (EYZB). This study demonstrates that EYZB exhibits > 147 times higher ionic conductivity of 0.44 S cm−1 at 600 °C compared to commercial Y-stabilized zirconia electrolyte with excellent stability over 1000 h. By rationally incorporating EYZB in composite electrodes and bilayer electrolytes, the zirconia-based electrolyte LT-SOC achieves the unprecedentedly high performance of 3.45 and 2.02 W cm−2 in the fuel cell mode and 2.08 and 0.95 A cm−2 in the electrolysis cell mode at 700 °C and 600 °C, respectively. Further, a distinctive microstructural feature of EYZB that largely extends triple phase boundary at the interface is revealed through digital twinning. This work provides insights for developing high-performance LT-SOCs.

AB - Despite the great potential of solid oxide electrochemical cells (SOCs) as highly efficient energy conversion devices, the undesirable high operating temperature limits their wider applicability. Herein, a novel approach to developing high-performance low-temperature SOCs (LT-SOCs) is presented through the use of an Er, Y, and Zr triple-doped bismuth oxide (EYZB). This study demonstrates that EYZB exhibits > 147 times higher ionic conductivity of 0.44 S cm−1 at 600 °C compared to commercial Y-stabilized zirconia electrolyte with excellent stability over 1000 h. By rationally incorporating EYZB in composite electrodes and bilayer electrolytes, the zirconia-based electrolyte LT-SOC achieves the unprecedentedly high performance of 3.45 and 2.02 W cm−2 in the fuel cell mode and 2.08 and 0.95 A cm−2 in the electrolysis cell mode at 700 °C and 600 °C, respectively. Further, a distinctive microstructural feature of EYZB that largely extends triple phase boundary at the interface is revealed through digital twinning. This work provides insights for developing high-performance LT-SOCs.

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KW - electrolysis cells

KW - first-principles calculations

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Lowering the Temperature of Solid Oxide Electrochemical Cells Using Triple-Doped Bismuth Oxides

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