Ultrathin Crystalline Silicon Nano and Micro Membranes with High Areal Density for Low-Cost Flexible Electronics

Ju Young Lee; Jongwoon Shin; Kyubeen Kim; Jeong Eun Ju; Ankan Dutta; Tae Soo Kim; Young Uk Cho; Taemin Kim; Luhing Hu; Won Kyung Min; Hyun Suh Jung; Young Sun Park; Sang Min Won; Woon Hong Yeo; Jooho Moon; Dahl Young Khang; Hyun Jae Kim; Jong Hyun Ahn; Huanyu Cheng; Ki Jun Yu; John A. Rogers

doi:10.1002/smll.202302597

Ultrathin Crystalline Silicon Nano and Micro Membranes with High Areal Density for Low-Cost Flexible Electronics

Ju Young Lee, Jongwoon Shin, Kyubeen Kim, Jeong Eun Ju, Ankan Dutta, Tae Soo Kim, Young Uk Cho, Taemin Kim, Luhing Hu, Won Kyung Min, Hyun Suh Jung, Young Sun Park, Sang Min Won, Woon Hong Yeo, Jooho Moon, Dahl Young Khang, Hyun Jae Kim, Jong Hyun Ahn, Huanyu Cheng, Ki Jun YuJohn A. Rogers

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

13 Citations (Scopus)

Abstract

Ultrathin crystalline silicon is widely used as an active material for high-performance, flexible, and stretchable electronics, from simple passive and active components to complex integrated circuits, due to its excellent electrical and mechanical properties. However, in contrast to conventional silicon wafer-based devices, ultrathin crystalline silicon-based electronics require an expensive and rather complicated fabrication process. Although silicon-on-insulator (SOI) wafers are commonly used to obtain a single layer of crystalline silicon, they are costly and difficult to process. Therefore, as an alternative to SOI wafers-based thin layers, here, a simple transfer method is proposed for printing ultrathin multiple crystalline silicon sheets with thicknesses between 300 nm to 13 µm and high areal density (>90%) from a single mother wafer. Theoretically, the silicon nano/micro membrane can be generated until the mother wafer is completely consumed. In addition, the electronic applications of silicon membranes are successfully demonstrated through the fabrication of a flexible solar cell and flexible NMOS transistor arrays.

Original language	English
Article number	2302597
Journal	Small
Volume	19
Issue number	39
DOIs	https://doi.org/10.1002/smll.202302597
Publication status	Published - 2023 Sept 27

Bibliographical note

Publisher Copyright:
© 2023 Wiley-VCH GmbH.

All Science Journal Classification (ASJC) codes

Biotechnology
General Chemistry
Biomaterials
General Materials Science
Engineering (miscellaneous)

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Lee, J. Y., Shin, J., Kim, K., Ju, J. E., Dutta, A., Kim, T. S., Cho, Y. U., Kim, T., Hu, L., Min, W. K., Jung, H. S., Park, Y. S., Won, S. M., Yeo, W. H., Moon, J., Khang, D. Y., Kim, H. J., Ahn, J. H., Cheng, H., ... Rogers, J. A. (2023). Ultrathin Crystalline Silicon Nano and Micro Membranes with High Areal Density for Low-Cost Flexible Electronics. Small, 19(39), Article 2302597. https://doi.org/10.1002/smll.202302597

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title = "Ultrathin Crystalline Silicon Nano and Micro Membranes with High Areal Density for Low-Cost Flexible Electronics",

abstract = "Ultrathin crystalline silicon is widely used as an active material for high-performance, flexible, and stretchable electronics, from simple passive and active components to complex integrated circuits, due to its excellent electrical and mechanical properties. However, in contrast to conventional silicon wafer-based devices, ultrathin crystalline silicon-based electronics require an expensive and rather complicated fabrication process. Although silicon-on-insulator (SOI) wafers are commonly used to obtain a single layer of crystalline silicon, they are costly and difficult to process. Therefore, as an alternative to SOI wafers-based thin layers, here, a simple transfer method is proposed for printing ultrathin multiple crystalline silicon sheets with thicknesses between 300 nm to 13 µm and high areal density (>90%) from a single mother wafer. Theoretically, the silicon nano/micro membrane can be generated until the mother wafer is completely consumed. In addition, the electronic applications of silicon membranes are successfully demonstrated through the fabrication of a flexible solar cell and flexible NMOS transistor arrays.",

keywords = "flexible electronics, reusable silicon, semiconductor electronics applications, silicon nano/micro membrane sheet transfer",

author = "Lee, {Ju Young} and Jongwoon Shin and Kyubeen Kim and Ju, {Jeong Eun} and Ankan Dutta and Kim, {Tae Soo} and Cho, {Young Uk} and Taemin Kim and Luhing Hu and Min, {Won Kyung} and Jung, {Hyun Suh} and Park, {Young Sun} and Won, {Sang Min} and Yeo, {Woon Hong} and Jooho Moon and Khang, {Dahl Young} and Kim, {Hyun Jae} and Ahn, {Jong Hyun} and Huanyu Cheng and Yu, {Ki Jun} and Rogers, {John A.}",

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year = "2023",

month = sep,

day = "27",

doi = "10.1002/smll.202302597",

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Lee, JY, Shin, J, Kim, K, Ju, JE, Dutta, A, Kim, TS, Cho, YU, Kim, T, Hu, L, Min, WK, Jung, HS, Park, YS, Won, SM, Yeo, WH, Moon, J , Khang, DY , Kim, HJ , Ahn, JH, Cheng, H, Yu, KJ & Rogers, JA 2023, 'Ultrathin Crystalline Silicon Nano and Micro Membranes with High Areal Density for Low-Cost Flexible Electronics', Small, vol. 19, no. 39, 2302597. https://doi.org/10.1002/smll.202302597

TY - JOUR

T1 - Ultrathin Crystalline Silicon Nano and Micro Membranes with High Areal Density for Low-Cost Flexible Electronics

AU - Lee, Ju Young

AU - Shin, Jongwoon

AU - Kim, Kyubeen

AU - Ju, Jeong Eun

AU - Dutta, Ankan

AU - Kim, Tae Soo

AU - Cho, Young Uk

AU - Kim, Taemin

AU - Hu, Luhing

AU - Min, Won Kyung

AU - Jung, Hyun Suh

AU - Park, Young Sun

AU - Won, Sang Min

AU - Yeo, Woon Hong

AU - Moon, Jooho

AU - Khang, Dahl Young

AU - Kim, Hyun Jae

AU - Ahn, Jong Hyun

AU - Cheng, Huanyu

AU - Yu, Ki Jun

AU - Rogers, John A.

PY - 2023/9/27

Y1 - 2023/9/27

N2 - Ultrathin crystalline silicon is widely used as an active material for high-performance, flexible, and stretchable electronics, from simple passive and active components to complex integrated circuits, due to its excellent electrical and mechanical properties. However, in contrast to conventional silicon wafer-based devices, ultrathin crystalline silicon-based electronics require an expensive and rather complicated fabrication process. Although silicon-on-insulator (SOI) wafers are commonly used to obtain a single layer of crystalline silicon, they are costly and difficult to process. Therefore, as an alternative to SOI wafers-based thin layers, here, a simple transfer method is proposed for printing ultrathin multiple crystalline silicon sheets with thicknesses between 300 nm to 13 µm and high areal density (>90%) from a single mother wafer. Theoretically, the silicon nano/micro membrane can be generated until the mother wafer is completely consumed. In addition, the electronic applications of silicon membranes are successfully demonstrated through the fabrication of a flexible solar cell and flexible NMOS transistor arrays.

AB - Ultrathin crystalline silicon is widely used as an active material for high-performance, flexible, and stretchable electronics, from simple passive and active components to complex integrated circuits, due to its excellent electrical and mechanical properties. However, in contrast to conventional silicon wafer-based devices, ultrathin crystalline silicon-based electronics require an expensive and rather complicated fabrication process. Although silicon-on-insulator (SOI) wafers are commonly used to obtain a single layer of crystalline silicon, they are costly and difficult to process. Therefore, as an alternative to SOI wafers-based thin layers, here, a simple transfer method is proposed for printing ultrathin multiple crystalline silicon sheets with thicknesses between 300 nm to 13 µm and high areal density (>90%) from a single mother wafer. Theoretically, the silicon nano/micro membrane can be generated until the mother wafer is completely consumed. In addition, the electronic applications of silicon membranes are successfully demonstrated through the fabrication of a flexible solar cell and flexible NMOS transistor arrays.

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KW - reusable silicon

KW - semiconductor electronics applications

KW - silicon nano/micro membrane sheet transfer

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Ultrathin Crystalline Silicon Nano and Micro Membranes with High Areal Density for Low-Cost Flexible Electronics

Abstract

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