Toward next-generation fuel cell materials

M. A.K.Yousaf Shah; Peter D. Lund; Bin Zhu

doi:10.1016/j.isci.2023.106869

Toward next-generation fuel cell materials

M. A.K.Yousaf Shah
, Peter D. Lund
, Bin Zhu

Research output: Contribution to journal › Review article › peer-review

23 Scopus citations

Abstract

The fuel cell's three layers—anode/electrolyte/cathode—convert fuel's chemical energy into electricity. Electrolyte membranes determine fuel cell types. Solid-state and ceramic electrolyte SOFC/PCFC and polymer based PEMFC fuel cells dominate fuel cell research. We present a new fuel cell concept using next-generation ceramic nanocomposites made of semiconductor-ionic material combinations. A built-in electric field driving mechanism boosts ionic (O²⁻ or H⁺ or both) conductivity in these materials. In a fuel cell device, non-doped ceria or its heterostructure might attain 1 Wcm⁻² power density. We reviewed promising functional nanocomposites for that range. Ceria-based and multifunctional semiconductor-ionic electrolytes will be highlighted. Owing to their simplicity and abundant resources, these materials might be used to make fuel cells cheaper and more accessible.

Original language	English
Article number	106869
Journal	iScience
Volume	26
Issue number	6
DOIs	https://doi.org/10.1016/j.isci.2023.106869
State	Published - 16 Jun 2023
Externally published	Yes

Keywords

Electrochemical materials science
Energy engineering
Materials property

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10.1016/j.isci.2023.106869

Cite this

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title = "Toward next-generation fuel cell materials",

abstract = "The fuel cell's three layers—anode/electrolyte/cathode—convert fuel's chemical energy into electricity. Electrolyte membranes determine fuel cell types. Solid-state and ceramic electrolyte SOFC/PCFC and polymer based PEMFC fuel cells dominate fuel cell research. We present a new fuel cell concept using next-generation ceramic nanocomposites made of semiconductor-ionic material combinations. A built-in electric field driving mechanism boosts ionic (O2− or H+ or both) conductivity in these materials. In a fuel cell device, non-doped ceria or its heterostructure might attain 1 Wcm−2 power density. We reviewed promising functional nanocomposites for that range. Ceria-based and multifunctional semiconductor-ionic electrolytes will be highlighted. Owing to their simplicity and abundant resources, these materials might be used to make fuel cells cheaper and more accessible.",

keywords = "Electrochemical materials science, Energy engineering, Materials property",

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year = "2023",

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doi = "10.1016/j.isci.2023.106869",

language = "英语",

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T1 - Toward next-generation fuel cell materials

AU - Shah, M. A.K.Yousaf

AU - Lund, Peter D.

AU - Zhu, Bin

PY - 2023/6/16

Y1 - 2023/6/16

N2 - The fuel cell's three layers—anode/electrolyte/cathode—convert fuel's chemical energy into electricity. Electrolyte membranes determine fuel cell types. Solid-state and ceramic electrolyte SOFC/PCFC and polymer based PEMFC fuel cells dominate fuel cell research. We present a new fuel cell concept using next-generation ceramic nanocomposites made of semiconductor-ionic material combinations. A built-in electric field driving mechanism boosts ionic (O2− or H+ or both) conductivity in these materials. In a fuel cell device, non-doped ceria or its heterostructure might attain 1 Wcm−2 power density. We reviewed promising functional nanocomposites for that range. Ceria-based and multifunctional semiconductor-ionic electrolytes will be highlighted. Owing to their simplicity and abundant resources, these materials might be used to make fuel cells cheaper and more accessible.

AB - The fuel cell's three layers—anode/electrolyte/cathode—convert fuel's chemical energy into electricity. Electrolyte membranes determine fuel cell types. Solid-state and ceramic electrolyte SOFC/PCFC and polymer based PEMFC fuel cells dominate fuel cell research. We present a new fuel cell concept using next-generation ceramic nanocomposites made of semiconductor-ionic material combinations. A built-in electric field driving mechanism boosts ionic (O2− or H+ or both) conductivity in these materials. In a fuel cell device, non-doped ceria or its heterostructure might attain 1 Wcm−2 power density. We reviewed promising functional nanocomposites for that range. Ceria-based and multifunctional semiconductor-ionic electrolytes will be highlighted. Owing to their simplicity and abundant resources, these materials might be used to make fuel cells cheaper and more accessible.

KW - Electrochemical materials science

KW - Energy engineering

KW - Materials property

UR - https://www.scopus.com/pages/publications/85160445566

U2 - 10.1016/j.isci.2023.106869

DO - 10.1016/j.isci.2023.106869

M3 - 文献综述

AN - SCOPUS:85160445566

SN - 2589-0042

VL - 26

JO - iScience

JF - iScience

IS - 6

M1 - 106869

ER -

Toward next-generation fuel cell materials

Abstract

Keywords

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