High proton conductivity through angstrom-porous titania

Y Ji; Guang Ping Hao; Yong Tao Tan; W. Q. Xiong; Y. Liu; W. Z. Zhou; D. -M. Tang; R. Z. Ma; S. J. Yuan; T. Sasaki; Marcelo Lozada Hidalgo; Andre Geim; Pengzhan Sun

doi:10.1038/s41467-024-54544-z

High proton conductivity through angstrom-porous titania

Y Ji, Guang Ping Hao, Yong Tao Tan, W. Q. Xiong, Y. Liu, W. Z. Zhou, D. -M. Tang, R. Z. Ma, S. J. Yuan, T. Sasaki, Marcelo Lozada Hidalgo, Andre Geim, Pengzhan Sun

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Abstract

Two dimensional (2D) crystals have attracted strong interest as a new class of proton conducting materials that can block atoms, molecules and ions while allowing proton transport through the atomically thin basal planes. Although 2D materials exhibit this perfect selectivity, the reported proton conductivities have been relatively low. Here we show that vacancy-rich titania monolayers are highly permeable to protons while remaining impermeable to helium with proton conductivity exceeding 100 S cm-2 at 200 C and surpassing targets set by industry roadmaps. The fast and selective proton transport is attributed to an extremely high density of titanium-atom vacancies (one per square nm), which effectively turns titania monolayers into angstrom-scale sieves. Our findings highlight the potential of 2D oxides as membrane materials for hydrogen-based technologies.

Original language	English
Article number	10546
Journal	Nature Communications
Volume	15
DOIs	https://doi.org/10.1038/s41467-024-54544-z https://doi.org/10.1038/s41467-024-54544-z
Publication status	Published - 4 Dec 2024

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title = "High proton conductivity through angstrom-porous titania",

abstract = " Two dimensional (2D) crystals have attracted strong interest as a new class of proton conducting materials that can block atoms, molecules and ions while allowing proton transport through the atomically thin basal planes. Although 2D materials exhibit this perfect selectivity, the reported proton conductivities have been relatively low. Here we show that vacancy-rich titania monolayers are highly permeable to protons while remaining impermeable to helium with proton conductivity exceeding 100 S cm-2 at 200 C and surpassing targets set by industry roadmaps. The fast and selective proton transport is attributed to an extremely high density of titanium-atom vacancies (one per square nm), which effectively turns titania monolayers into angstrom-scale sieves. Our findings highlight the potential of 2D oxides as membrane materials for hydrogen-based technologies. ",

author = "Y Ji and Hao, {Guang Ping} and Tan, {Yong Tao} and Xiong, {W. Q.} and Y. Liu and Zhou, {W. Z.} and Tang, {D. -M.} and Ma, {R. Z.} and Yuan, {S. J.} and T. Sasaki and {Lozada Hidalgo}, Marcelo and Andre Geim and Pengzhan Sun",

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doi = "10.1038/s41467-024-54544-z",

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TY - JOUR

T1 - High proton conductivity through angstrom-porous titania

AU - Ji, Y

AU - Hao, Guang Ping

AU - Tan, Yong Tao

AU - Xiong, W. Q.

AU - Liu, Y.

AU - Zhou, W. Z.

AU - Tang, D. -M.

AU - Ma, R. Z.

AU - Yuan, S. J.

AU - Sasaki, T.

AU - Lozada Hidalgo, Marcelo

AU - Geim, Andre

AU - Sun, Pengzhan

PY - 2024/12/4

Y1 - 2024/12/4

N2 - Two dimensional (2D) crystals have attracted strong interest as a new class of proton conducting materials that can block atoms, molecules and ions while allowing proton transport through the atomically thin basal planes. Although 2D materials exhibit this perfect selectivity, the reported proton conductivities have been relatively low. Here we show that vacancy-rich titania monolayers are highly permeable to protons while remaining impermeable to helium with proton conductivity exceeding 100 S cm-2 at 200 C and surpassing targets set by industry roadmaps. The fast and selective proton transport is attributed to an extremely high density of titanium-atom vacancies (one per square nm), which effectively turns titania monolayers into angstrom-scale sieves. Our findings highlight the potential of 2D oxides as membrane materials for hydrogen-based technologies.

AB - Two dimensional (2D) crystals have attracted strong interest as a new class of proton conducting materials that can block atoms, molecules and ions while allowing proton transport through the atomically thin basal planes. Although 2D materials exhibit this perfect selectivity, the reported proton conductivities have been relatively low. Here we show that vacancy-rich titania monolayers are highly permeable to protons while remaining impermeable to helium with proton conductivity exceeding 100 S cm-2 at 200 C and surpassing targets set by industry roadmaps. The fast and selective proton transport is attributed to an extremely high density of titanium-atom vacancies (one per square nm), which effectively turns titania monolayers into angstrom-scale sieves. Our findings highlight the potential of 2D oxides as membrane materials for hydrogen-based technologies.

U2 - 10.1038/s41467-024-54544-z

DO - 10.1038/s41467-024-54544-z

M3 - Article

SN - 2041-1723

VL - 15

JO - Nature Communications

JF - Nature Communications

M1 - 10546

ER -

High proton conductivity through angstrom-porous titania

Abstract

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