Printed Transistors on Paper: Towards Smart Consumer Product Packaging

The integration of fully printed transistors on low cost paper substrates compatible with roll‐to‐roll processes is demonstrated here. Printed electronics promises to enable a range of technologies on paper including printed sensors, RF tags, and displays. However, progress has been slow due to the...

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Veröffentlicht in:	Advanced functional materials 2014-08, Vol.24 (32), p.5067-5074
Hauptverfasser:	Grau, Gerd, Kitsomboonloha, Rungrot, Swisher, Sarah L., Kang, Hongki, Subramanian, Vivek
Format:	Artikel
Sprache:	eng
Schlagworte:	Electronics gravure printing locally printed smoothing layers organic field effect transistors paper substrates Printing Roughness Semiconductor devices Semiconductors Smoothing Transistors
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container_end_page	5074
container_issue	32
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container_title	Advanced functional materials
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creator	Grau, Gerd Kitsomboonloha, Rungrot Swisher, Sarah L. Kang, Hongki Subramanian, Vivek
description	The integration of fully printed transistors on low cost paper substrates compatible with roll‐to‐roll processes is demonstrated here. Printed electronics promises to enable a range of technologies on paper including printed sensors, RF tags, and displays. However, progress has been slow due to the paper roughness and ink absorption. This is solved here by employing gravure printing to print local smoothing pads that also act as an absorption barrier. This innovative local smoothing process retains desirable paper properties such as foldability, breathability, and biodegradability outside of electronically active areas. Atomic force microscopy measurements show significant improvements in roughness. The polymer ink and printing parameters are optimized to minimize ink absorption and printing artifacts when printing the smoothing layer. Organic thin film transistors (OTFT) are fabricated on top of this locally smoothed paper. OTFTs exhibit performance on par with previously reported printed transistors on plastic utilizing the same materials system (pBTTT semiconductor, poly‐4‐vinylphenol dielectric). OTFTs deliver saturation mobility approaching 0.1 cm2V–1s–1 and on‐off‐ratio of 3.2 × 104. This attests to the quality of the local smoothing, and points to a promising path for realizing electronics on paper. Fully printed transistors are demonstrated on paper substrates with performance on par with plastic based devices. Desirable paper properties such as foldability, breathability, and biodegradability are preserved outside of electronically active areas by an innovative locally printed smoothing process. This process is fully compatible with existing paper packaging process flows.
doi_str_mv	10.1002/adfm.201400129
format	Article
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Printed electronics promises to enable a range of technologies on paper including printed sensors, RF tags, and displays. However, progress has been slow due to the paper roughness and ink absorption. This is solved here by employing gravure printing to print local smoothing pads that also act as an absorption barrier. This innovative local smoothing process retains desirable paper properties such as foldability, breathability, and biodegradability outside of electronically active areas. Atomic force microscopy measurements show significant improvements in roughness. The polymer ink and printing parameters are optimized to minimize ink absorption and printing artifacts when printing the smoothing layer. Organic thin film transistors (OTFT) are fabricated on top of this locally smoothed paper. OTFTs exhibit performance on par with previously reported printed transistors on plastic utilizing the same materials system (pBTTT semiconductor, poly‐4‐vinylphenol dielectric). OTFTs deliver saturation mobility approaching 0.1 cm2V–1s–1 and on‐off‐ratio of 3.2 × 104. This attests to the quality of the local smoothing, and points to a promising path for realizing electronics on paper. Fully printed transistors are demonstrated on paper substrates with performance on par with plastic based devices. Desirable paper properties such as foldability, breathability, and biodegradability are preserved outside of electronically active areas by an innovative locally printed smoothing process. This process is fully compatible with existing paper packaging process flows.</description><identifier>ISSN: 1616-301X</identifier><identifier>EISSN: 1616-3028</identifier><identifier>DOI: 10.1002/adfm.201400129</identifier><language>eng</language><publisher>Blackwell Publishing Ltd</publisher><subject>Electronics ; gravure printing ; locally printed smoothing layers ; organic field effect transistors ; paper substrates ; Printing ; Roughness ; Semiconductor devices ; Semiconductors ; Smoothing ; Transistors</subject><ispartof>Advanced functional materials, 2014-08, Vol.24 (32), p.5067-5074</ispartof><rights>2014 WILEY‐VCH Verlag GmbH & Co. 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Funct. Mater</addtitle><description>The integration of fully printed transistors on low cost paper substrates compatible with roll‐to‐roll processes is demonstrated here. Printed electronics promises to enable a range of technologies on paper including printed sensors, RF tags, and displays. However, progress has been slow due to the paper roughness and ink absorption. This is solved here by employing gravure printing to print local smoothing pads that also act as an absorption barrier. This innovative local smoothing process retains desirable paper properties such as foldability, breathability, and biodegradability outside of electronically active areas. Atomic force microscopy measurements show significant improvements in roughness. The polymer ink and printing parameters are optimized to minimize ink absorption and printing artifacts when printing the smoothing layer. Organic thin film transistors (OTFT) are fabricated on top of this locally smoothed paper. 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Funct. Mater</addtitle><date>2014-08-27</date><risdate>2014</risdate><volume>24</volume><issue>32</issue><spage>5067</spage><epage>5074</epage><pages>5067-5074</pages><issn>1616-301X</issn><eissn>1616-3028</eissn><abstract>The integration of fully printed transistors on low cost paper substrates compatible with roll‐to‐roll processes is demonstrated here. Printed electronics promises to enable a range of technologies on paper including printed sensors, RF tags, and displays. However, progress has been slow due to the paper roughness and ink absorption. This is solved here by employing gravure printing to print local smoothing pads that also act as an absorption barrier. This innovative local smoothing process retains desirable paper properties such as foldability, breathability, and biodegradability outside of electronically active areas. Atomic force microscopy measurements show significant improvements in roughness. The polymer ink and printing parameters are optimized to minimize ink absorption and printing artifacts when printing the smoothing layer. Organic thin film transistors (OTFT) are fabricated on top of this locally smoothed paper. OTFTs exhibit performance on par with previously reported printed transistors on plastic utilizing the same materials system (pBTTT semiconductor, poly‐4‐vinylphenol dielectric). OTFTs deliver saturation mobility approaching 0.1 cm2V–1s–1 and on‐off‐ratio of 3.2 × 104. This attests to the quality of the local smoothing, and points to a promising path for realizing electronics on paper. Fully printed transistors are demonstrated on paper substrates with performance on par with plastic based devices. Desirable paper properties such as foldability, breathability, and biodegradability are preserved outside of electronically active areas by an innovative locally printed smoothing process. This process is fully compatible with existing paper packaging process flows.</abstract><pub>Blackwell Publishing Ltd</pub><doi>10.1002/adfm.201400129</doi><tpages>8</tpages></addata></record>
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subjects	Electronics gravure printing locally printed smoothing layers organic field effect transistors paper substrates Printing Roughness Semiconductor devices Semiconductors Smoothing Transistors
title	Printed Transistors on Paper: Towards Smart Consumer Product Packaging
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