Quantum confinement effects in transferrable silicon nanomembranes and their applications on unusual substrates

Houk Jang; Wonho Lee; Sang M. Won; Seoung Yoon Ryu; Donghun Lee; Jae Bon Koo; Seong Deok Ahn; Cheol Woong Yang; Moon Ho Jo; Jeong Ho Cho; John A. Rogers; Jong Hyun Ahn

doi:10.1021/nl403251e

Quantum confinement effects in transferrable silicon nanomembranes and their applications on unusual substrates

Houk Jang, Wonho Lee, Sang M. Won, Seoung Yoon Ryu, Donghun Lee, Jae Bon Koo, Seong Deok Ahn, Cheol Woong Yang, Moon Ho Jo, Jeong Ho Cho, John A. Rogers, Jong Hyun Ahn

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

Abstract

Two dimensional (2D) semiconductors have attracted attention for a range of electronic applications, such as transparent, flexible field effect transistors and sensors owing to their good optical transparency and mechanical flexibility. Efforts to exploit 2D semiconductors in electronics are hampered, however, by the lack of efficient methods for their synthesis at levels of quality, uniformity, and reliability needed for practical applications. Here, as an alternative 2D semiconductor, we study single crystal Si nanomembranes (NMs), formed in large area sheets with precisely defined thicknesses ranging from 1.4 to 10 nm. These Si NMs exhibit electronic properties of two-dimensional quantum wells and offer exceptionally high optical transparency and low flexural rigidity. Deterministic assembly techniques allow integration of these materials into unusual device architectures, including field effect transistors with total thicknesses of less than 12 nm, for potential use in transparent, flexible, and stretchable forms of electronics.

Original language	English (US)
Pages (from-to)	5600-5607
Number of pages	8
Journal	Nano letters
Volume	13
Issue number	11
DOIs	https://doi.org/10.1021/nl403251e
State	Published - Nov 13 2013
Externally published	Yes

Keywords

flexible electronics
graphene
quantum confinement
single-crystal silicon
transparent transistor
Two-dimensional material

ASJC Scopus subject areas

Condensed Matter Physics
Bioengineering
General Chemistry
General Materials Science
Mechanical Engineering

Online availability

10.1021/nl403251e

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title = "Quantum confinement effects in transferrable silicon nanomembranes and their applications on unusual substrates",

abstract = "Two dimensional (2D) semiconductors have attracted attention for a range of electronic applications, such as transparent, flexible field effect transistors and sensors owing to their good optical transparency and mechanical flexibility. Efforts to exploit 2D semiconductors in electronics are hampered, however, by the lack of efficient methods for their synthesis at levels of quality, uniformity, and reliability needed for practical applications. Here, as an alternative 2D semiconductor, we study single crystal Si nanomembranes (NMs), formed in large area sheets with precisely defined thicknesses ranging from 1.4 to 10 nm. These Si NMs exhibit electronic properties of two-dimensional quantum wells and offer exceptionally high optical transparency and low flexural rigidity. Deterministic assembly techniques allow integration of these materials into unusual device architectures, including field effect transistors with total thicknesses of less than 12 nm, for potential use in transparent, flexible, and stretchable forms of electronics.",

keywords = "flexible electronics, graphene, quantum confinement, single-crystal silicon, transparent transistor, Two-dimensional material",

author = "Houk Jang and Wonho Lee and Won, {Sang M.} and Ryu, {Seoung Yoon} and Donghun Lee and Koo, {Jae Bon} and Ahn, {Seong Deok} and Yang, {Cheol Woong} and Jo, {Moon Ho} and Cho, {Jeong Ho} and Rogers, {John A.} and Ahn, {Jong Hyun}",

year = "2013",

month = nov,

day = "13",

doi = "10.1021/nl403251e",

language = "English (US)",

volume = "13",

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AU - Jang, Houk

AU - Lee, Wonho

AU - Won, Sang M.

AU - Ryu, Seoung Yoon

AU - Lee, Donghun

AU - Koo, Jae Bon

AU - Ahn, Seong Deok

AU - Yang, Cheol Woong

AU - Jo, Moon Ho

AU - Cho, Jeong Ho

AU - Rogers, John A.

AU - Ahn, Jong Hyun

PY - 2013/11/13

Y1 - 2013/11/13

N2 - Two dimensional (2D) semiconductors have attracted attention for a range of electronic applications, such as transparent, flexible field effect transistors and sensors owing to their good optical transparency and mechanical flexibility. Efforts to exploit 2D semiconductors in electronics are hampered, however, by the lack of efficient methods for their synthesis at levels of quality, uniformity, and reliability needed for practical applications. Here, as an alternative 2D semiconductor, we study single crystal Si nanomembranes (NMs), formed in large area sheets with precisely defined thicknesses ranging from 1.4 to 10 nm. These Si NMs exhibit electronic properties of two-dimensional quantum wells and offer exceptionally high optical transparency and low flexural rigidity. Deterministic assembly techniques allow integration of these materials into unusual device architectures, including field effect transistors with total thicknesses of less than 12 nm, for potential use in transparent, flexible, and stretchable forms of electronics.

AB - Two dimensional (2D) semiconductors have attracted attention for a range of electronic applications, such as transparent, flexible field effect transistors and sensors owing to their good optical transparency and mechanical flexibility. Efforts to exploit 2D semiconductors in electronics are hampered, however, by the lack of efficient methods for their synthesis at levels of quality, uniformity, and reliability needed for practical applications. Here, as an alternative 2D semiconductor, we study single crystal Si nanomembranes (NMs), formed in large area sheets with precisely defined thicknesses ranging from 1.4 to 10 nm. These Si NMs exhibit electronic properties of two-dimensional quantum wells and offer exceptionally high optical transparency and low flexural rigidity. Deterministic assembly techniques allow integration of these materials into unusual device architectures, including field effect transistors with total thicknesses of less than 12 nm, for potential use in transparent, flexible, and stretchable forms of electronics.

KW - flexible electronics

KW - graphene

KW - quantum confinement

KW - single-crystal silicon

KW - transparent transistor

KW - Two-dimensional material

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Quantum confinement effects in transferrable silicon nanomembranes and their applications on unusual substrates

Abstract

Keywords

ASJC Scopus subject areas

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