Capillary Flow Printing of Submicron Carbon Nanotube Transistors
Although printed transistors have a wide range of applications, the limited resolution of printing techniques (10-30 um) has been a barrier to advancement and scaling, particularly down to submicron dimensions. While previous works have shown creative approaches to realizing submicron channel length...
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| Main Authors | , , , , , , , , , , , |
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| Format | Journal Article |
| Language | English |
| Published |
05.06.2024
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| Subjects | |
| Online Access | Get full text |
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| Abstract | Although printed transistors have a wide range of applications, the limited
resolution of printing techniques (10-30 um) has been a barrier to advancement
and scaling, particularly down to submicron dimensions. While previous works
have shown creative approaches to realizing submicron channel lengths with
printing, reliance on chemical processes unique to specific inks or tedious
post-processing limit their applicability. Here, we report the use of capillary
flow printing (CFP) to repeatably create fully printed submicron carbon
nanotube thin-film transistors (CNT-TFTs) without chemical modification or
physical manipulation post-printing. The versatility of this printing technique
is demonstrated by printing conducting, semiconducting, and insulating inks on
several types of substrates (SiO2, Kapton, and paper) and through the
fabrication of various TFT device (contacting/gating) architectures. Notably,
CFP of these CNT-TFTs yielded on-currents of 1.12 mA/mm when back gated on
Si/SiO2, and 490 uA/mm when side gated through ion gel on Kapton, demonstrating
the strong transistor performance achievable with CFP. Mechanical bending and
sweep rate resilience of devices printed on Kapton show the wide utility of
CFP-fabricated devices for flexible applications. This work highlights the
ability of CFP as a viable fabrication method for submicron electronics through
cleanroom-free printing techniques. |
|---|---|
| AbstractList | Although printed transistors have a wide range of applications, the limited
resolution of printing techniques (10-30 um) has been a barrier to advancement
and scaling, particularly down to submicron dimensions. While previous works
have shown creative approaches to realizing submicron channel lengths with
printing, reliance on chemical processes unique to specific inks or tedious
post-processing limit their applicability. Here, we report the use of capillary
flow printing (CFP) to repeatably create fully printed submicron carbon
nanotube thin-film transistors (CNT-TFTs) without chemical modification or
physical manipulation post-printing. The versatility of this printing technique
is demonstrated by printing conducting, semiconducting, and insulating inks on
several types of substrates (SiO2, Kapton, and paper) and through the
fabrication of various TFT device (contacting/gating) architectures. Notably,
CFP of these CNT-TFTs yielded on-currents of 1.12 mA/mm when back gated on
Si/SiO2, and 490 uA/mm when side gated through ion gel on Kapton, demonstrating
the strong transistor performance achievable with CFP. Mechanical bending and
sweep rate resilience of devices printed on Kapton show the wide utility of
CFP-fabricated devices for flexible applications. This work highlights the
ability of CFP as a viable fabrication method for submicron electronics through
cleanroom-free printing techniques. |
| Author | Smith, Brittany N Doherty, James L Salfity, Matthew Pascual, Marc Bigan, Nathan M'Barki, Amin Franklin, Aaron D Albarghouthi, Faris M Pei, Xuancheng Macfarlane, Quentin Badia, Daniel Boncenne, Pascal |
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| BackLink | https://doi.org/10.48550/arXiv.2406.03602$$DView paper in arXiv |
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| Snippet | Although printed transistors have a wide range of applications, the limited
resolution of printing techniques (10-30 um) has been a barrier to advancement
and... |
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| Title | Capillary Flow Printing of Submicron Carbon Nanotube Transistors |
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