Atomic-scale ion transistor with ultrahigh diffusivity

Yahui Xue; Yang Xia; Sui Yang; Yousif Alsaid; King Yan Fong; Yuan Wang; Xiang Zhang

doi:10.1126/science.abb5144

Atomic-scale ion transistor with ultrahigh diffusivity

Yahui Xue, Yang Xia, Sui Yang, Yousif Alsaid, King Yan Fong, Yuan Wang, Xiang Zhang

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

90 Scopus citations

Abstract

Biological ion channels rapidly and selectively gate ion transport through atomic-scale filters to maintain vital life functions. We report an atomic-scale ion transistor exhibiting ultrafast and highly selective ion transport controlled by electrical gating in graphene channels around 3 angstroms in height, made from a single flake of reduced graphene oxide. The ion diffusion coefficient reaches two orders of magnitude higher than the coefficient in bulk water. Atomic-scale ion transport shows a threshold behavior due to the critical energy barrier for hydrated ion insertion. Our in situ optical measurements suggest that ultrafast ion transport likely originates from highly dense packing of ions and their concerted movement inside the graphene channels.

Original language	English (US)
Pages (from-to)	501-503
Number of pages	3
Journal	Science
Volume	372
Issue number	6541
DOIs	https://doi.org/10.1126/science.abb5144
State	Published - Apr 30 2021
Externally published	Yes

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title = "Atomic-scale ion transistor with ultrahigh diffusivity",

abstract = "Biological ion channels rapidly and selectively gate ion transport through atomic-scale filters to maintain vital life functions. We report an atomic-scale ion transistor exhibiting ultrafast and highly selective ion transport controlled by electrical gating in graphene channels around 3 angstroms in height, made from a single flake of reduced graphene oxide. The ion diffusion coefficient reaches two orders of magnitude higher than the coefficient in bulk water. Atomic-scale ion transport shows a threshold behavior due to the critical energy barrier for hydrated ion insertion. Our in situ optical measurements suggest that ultrafast ion transport likely originates from highly dense packing of ions and their concerted movement inside the graphene channels.",

author = "Yahui Xue and Yang Xia and Sui Yang and Yousif Alsaid and Fong, {King Yan} and Yuan Wang and Xiang Zhang",

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AU - Xue, Yahui

AU - Xia, Yang

AU - Yang, Sui

AU - Alsaid, Yousif

AU - Fong, King Yan

AU - Wang, Yuan

AU - Zhang, Xiang

PY - 2021/4/30

Y1 - 2021/4/30

N2 - Biological ion channels rapidly and selectively gate ion transport through atomic-scale filters to maintain vital life functions. We report an atomic-scale ion transistor exhibiting ultrafast and highly selective ion transport controlled by electrical gating in graphene channels around 3 angstroms in height, made from a single flake of reduced graphene oxide. The ion diffusion coefficient reaches two orders of magnitude higher than the coefficient in bulk water. Atomic-scale ion transport shows a threshold behavior due to the critical energy barrier for hydrated ion insertion. Our in situ optical measurements suggest that ultrafast ion transport likely originates from highly dense packing of ions and their concerted movement inside the graphene channels.

AB - Biological ion channels rapidly and selectively gate ion transport through atomic-scale filters to maintain vital life functions. We report an atomic-scale ion transistor exhibiting ultrafast and highly selective ion transport controlled by electrical gating in graphene channels around 3 angstroms in height, made from a single flake of reduced graphene oxide. The ion diffusion coefficient reaches two orders of magnitude higher than the coefficient in bulk water. Atomic-scale ion transport shows a threshold behavior due to the critical energy barrier for hydrated ion insertion. Our in situ optical measurements suggest that ultrafast ion transport likely originates from highly dense packing of ions and their concerted movement inside the graphene channels.

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Atomic-scale ion transistor with ultrahigh diffusivity

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