A simple and rapid formation of wet chemical etched silicon nanowire films at the air-water interface

Tae Il Lee; Won Jin Choi; Kyeong Ju Moon; Ji Hyuk Choi; Jee Ho Park; Unyong Jeong; Hong Koo Baik; Jae Min Myoung

doi:10.1039/c1jm12167g

A simple and rapid formation of wet chemical etched silicon nanowire films at the air-water interface

Tae Il Lee, Won Jin Choi, Kyeong Ju Moon, Ji Hyuk Choi, Jee Ho Park, Unyong Jeong, Hong Koo Baik, Jae Min Myoung

Department of Materials Science and Engineering

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

7 Citations (Scopus)

Abstract

A spontaneous assembly route to form a thin film of nanowires (NWs) was demonstrated and its feasibility was confirmed through the fabrication of a high-performance multi-Si NW field effect transistor (FET) using this route. Governed by the three mechanisms of spreading, trapping, and two-dimensional packing, the route was optimized for the concentration of Si NWs and the initial volume ratio of aqueous hydrochloride solution to isopropyl alcohol. The successfully formed Si NW thin-film was transferred on a flat polydimethylsiloxane (PDMS) mold and regulated using a repeatable conformal contact method with a new flat PDMS to prepare it for decal printing on an organic dielectric layer. Finally, after depositing the source and drain electrodes on the printed active layer, a high-performance 23-bridged Si NW FET exhibiting a μ_eff of 51.4 cm² V^-1 s ^-1, an on/off drain current ratio of 10⁵, and a V _th of -2.7 V was obtained.

Original language	English
Pages (from-to)	14203-14208
Number of pages	6
Journal	Journal of Materials Chemistry
Volume	21
Issue number	37
DOIs	https://doi.org/10.1039/c1jm12167g
Publication status	Published - 2011 Oct 7

All Science Journal Classification (ASJC) codes

Chemistry(all)
Materials Chemistry

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10.1039/c1jm12167g

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title = "A simple and rapid formation of wet chemical etched silicon nanowire films at the air-water interface",

abstract = "A spontaneous assembly route to form a thin film of nanowires (NWs) was demonstrated and its feasibility was confirmed through the fabrication of a high-performance multi-Si NW field effect transistor (FET) using this route. Governed by the three mechanisms of spreading, trapping, and two-dimensional packing, the route was optimized for the concentration of Si NWs and the initial volume ratio of aqueous hydrochloride solution to isopropyl alcohol. The successfully formed Si NW thin-film was transferred on a flat polydimethylsiloxane (PDMS) mold and regulated using a repeatable conformal contact method with a new flat PDMS to prepare it for decal printing on an organic dielectric layer. Finally, after depositing the source and drain electrodes on the printed active layer, a high-performance 23-bridged Si NW FET exhibiting a μeff of 51.4 cm2 V-1 s -1, an on/off drain current ratio of 105, and a V th of -2.7 V was obtained.",

author = "Lee, {Tae Il} and Choi, {Won Jin} and Moon, {Kyeong Ju} and Choi, {Ji Hyuk} and Park, {Jee Ho} and Unyong Jeong and Baik, {Hong Koo} and Myoung, {Jae Min}",

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AU - Lee, Tae Il

AU - Choi, Won Jin

AU - Moon, Kyeong Ju

AU - Choi, Ji Hyuk

AU - Park, Jee Ho

AU - Jeong, Unyong

AU - Baik, Hong Koo

AU - Myoung, Jae Min

PY - 2011/10/7

Y1 - 2011/10/7

N2 - A spontaneous assembly route to form a thin film of nanowires (NWs) was demonstrated and its feasibility was confirmed through the fabrication of a high-performance multi-Si NW field effect transistor (FET) using this route. Governed by the three mechanisms of spreading, trapping, and two-dimensional packing, the route was optimized for the concentration of Si NWs and the initial volume ratio of aqueous hydrochloride solution to isopropyl alcohol. The successfully formed Si NW thin-film was transferred on a flat polydimethylsiloxane (PDMS) mold and regulated using a repeatable conformal contact method with a new flat PDMS to prepare it for decal printing on an organic dielectric layer. Finally, after depositing the source and drain electrodes on the printed active layer, a high-performance 23-bridged Si NW FET exhibiting a μeff of 51.4 cm2 V-1 s -1, an on/off drain current ratio of 105, and a V th of -2.7 V was obtained.

AB - A spontaneous assembly route to form a thin film of nanowires (NWs) was demonstrated and its feasibility was confirmed through the fabrication of a high-performance multi-Si NW field effect transistor (FET) using this route. Governed by the three mechanisms of spreading, trapping, and two-dimensional packing, the route was optimized for the concentration of Si NWs and the initial volume ratio of aqueous hydrochloride solution to isopropyl alcohol. The successfully formed Si NW thin-film was transferred on a flat polydimethylsiloxane (PDMS) mold and regulated using a repeatable conformal contact method with a new flat PDMS to prepare it for decal printing on an organic dielectric layer. Finally, after depositing the source and drain electrodes on the printed active layer, a high-performance 23-bridged Si NW FET exhibiting a μeff of 51.4 cm2 V-1 s -1, an on/off drain current ratio of 105, and a V th of -2.7 V was obtained.

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A simple and rapid formation of wet chemical etched silicon nanowire films at the air-water interface

Abstract

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