Soft Electronics Manufacturing Using Microcontact Printing

This work describes a microcontact printing (µCP) process for reproducible manufacturing of liquid gallium alloy–based soft and stretchable electronics. One of the leading approaches to create soft and stretchable electronics involves embedding liquid metals (LM) into an elastomer matrix. Although t...

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Veröffentlicht in:	Advanced functional materials 2019-12, Vol.29 (51), p.n/a
Hauptverfasser:	Yalcintas, Ezgi Pinar, Ozutemiz, Kadri Bugra, Cetinkaya, Toygun, Dalloro, Livio, Majidi, Carmel, Ozdoganlar, O. Burak
Format:	Artikel
Sprache:	eng
Schlagworte:	Commercialization Deformation EGaIn elastomer circuits Elastomers Electronics Formability Gallium base alloys liquid metal Liquid metals Manufacturing Materials science microcontact printing Production methods soft electronics stretchable microelectronics Substrates wearable electronics
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container_title	Advanced functional materials
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creator	Yalcintas, Ezgi Pinar Ozutemiz, Kadri Bugra Cetinkaya, Toygun Dalloro, Livio Majidi, Carmel Ozdoganlar, O. Burak
description	This work describes a microcontact printing (µCP) process for reproducible manufacturing of liquid gallium alloy–based soft and stretchable electronics. One of the leading approaches to create soft and stretchable electronics involves embedding liquid metals (LM) into an elastomer matrix. Although the advantages of liquid metal–based electronics have been well established, their mainstream adoption and commercialization necessitates development of precise and scalable manufacturing methods. To address this need, a scalable µCP process is presented that uses surface‐functionalized, reusable rigid, or deformable stamps to transfer eutectic gallium–indium (EGaIn) patterns onto elastomer substrates. A novel approach is developed to create the surface‐functionalized stamps, enabling selective transfer of LM to desired locations on a substrate without residues or electrical shorts. To address the critical needs of precise and reproducible positioning, alignment, and stamping force application, a high‐precision automated µCP system is designed. After describing the approach, the precision of stamps is evaluated and EGaIn features (as small as 15 µm line width), as well as electrical functionality of printed circuits with and without deformation, are fabricated. The presented process addresses many of the limitations associated with the alternative fabrication processes, and thus provides an effective approach for scalable fabrication of LM‐based soft and stretchable microelectronics. A novel microcontact printing process is described for reproducible manufacturing of liquid gallium alloy–based soft and stretchable electronics. The presented microcontact printing process addresses many of the limitations associated with the alternative fabrication processes, and thus provides an effective approach for scalable fabrication of liquid metal–based soft and stretchable microelectronics.
doi_str_mv	10.1002/adfm.201906551
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Burak</creator><creatorcontrib>Yalcintas, Ezgi Pinar ; Ozutemiz, Kadri Bugra ; Cetinkaya, Toygun ; Dalloro, Livio ; Majidi, Carmel ; Ozdoganlar, O. Burak</creatorcontrib><description>This work describes a microcontact printing (µCP) process for reproducible manufacturing of liquid gallium alloy–based soft and stretchable electronics. One of the leading approaches to create soft and stretchable electronics involves embedding liquid metals (LM) into an elastomer matrix. Although the advantages of liquid metal–based electronics have been well established, their mainstream adoption and commercialization necessitates development of precise and scalable manufacturing methods. To address this need, a scalable µCP process is presented that uses surface‐functionalized, reusable rigid, or deformable stamps to transfer eutectic gallium–indium (EGaIn) patterns onto elastomer substrates. A novel approach is developed to create the surface‐functionalized stamps, enabling selective transfer of LM to desired locations on a substrate without residues or electrical shorts. To address the critical needs of precise and reproducible positioning, alignment, and stamping force application, a high‐precision automated µCP system is designed. After describing the approach, the precision of stamps is evaluated and EGaIn features (as small as 15 µm line width), as well as electrical functionality of printed circuits with and without deformation, are fabricated. The presented process addresses many of the limitations associated with the alternative fabrication processes, and thus provides an effective approach for scalable fabrication of LM‐based soft and stretchable microelectronics. A novel microcontact printing process is described for reproducible manufacturing of liquid gallium alloy–based soft and stretchable electronics. 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Burak</creatorcontrib><title>Soft Electronics Manufacturing Using Microcontact Printing</title><title>Advanced functional materials</title><description>This work describes a microcontact printing (µCP) process for reproducible manufacturing of liquid gallium alloy–based soft and stretchable electronics. One of the leading approaches to create soft and stretchable electronics involves embedding liquid metals (LM) into an elastomer matrix. Although the advantages of liquid metal–based electronics have been well established, their mainstream adoption and commercialization necessitates development of precise and scalable manufacturing methods. To address this need, a scalable µCP process is presented that uses surface‐functionalized, reusable rigid, or deformable stamps to transfer eutectic gallium–indium (EGaIn) patterns onto elastomer substrates. A novel approach is developed to create the surface‐functionalized stamps, enabling selective transfer of LM to desired locations on a substrate without residues or electrical shorts. To address the critical needs of precise and reproducible positioning, alignment, and stamping force application, a high‐precision automated µCP system is designed. After describing the approach, the precision of stamps is evaluated and EGaIn features (as small as 15 µm line width), as well as electrical functionality of printed circuits with and without deformation, are fabricated. The presented process addresses many of the limitations associated with the alternative fabrication processes, and thus provides an effective approach for scalable fabrication of LM‐based soft and stretchable microelectronics. A novel microcontact printing process is described for reproducible manufacturing of liquid gallium alloy–based soft and stretchable electronics. 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Burak</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c4411-90dc502655aabf3034770b58e69446f3a3866baff819a8c8e3ee415c0cb508f73</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2019</creationdate><topic>Commercialization</topic><topic>Deformation</topic><topic>EGaIn</topic><topic>elastomer circuits</topic><topic>Elastomers</topic><topic>Electronics</topic><topic>Formability</topic><topic>Gallium base alloys</topic><topic>liquid metal</topic><topic>Liquid metals</topic><topic>Manufacturing</topic><topic>Materials science</topic><topic>microcontact printing</topic><topic>Production methods</topic><topic>soft electronics</topic><topic>stretchable microelectronics</topic><topic>Substrates</topic><topic>wearable electronics</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Yalcintas, Ezgi Pinar</creatorcontrib><creatorcontrib>Ozutemiz, Kadri Bugra</creatorcontrib><creatorcontrib>Cetinkaya, Toygun</creatorcontrib><creatorcontrib>Dalloro, Livio</creatorcontrib><creatorcontrib>Majidi, Carmel</creatorcontrib><creatorcontrib>Ozdoganlar, O. 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subjects	Commercialization Deformation EGaIn elastomer circuits Elastomers Electronics Formability Gallium base alloys liquid metal Liquid metals Manufacturing Materials science microcontact printing Production methods soft electronics stretchable microelectronics Substrates wearable electronics
title	Soft Electronics Manufacturing Using Microcontact Printing
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