Journal
ADVANCED MATERIALS TECHNOLOGIES
Volume 7, Issue 2, Pages -Publisher
WILEY
DOI: 10.1002/admt.202000798
Keywords
3D printing; fused deposition modeling; inkjet printing; neuromorphic devices; organic electrochemical transistors
Categories
Funding
- EPSRC Centre for Doctoral Training in Ultra Precision Engineering [EP/L016567/1]
- Leading Young Researcher Overseas Visit Program from Tohoku University
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Organic electrochemical transistors (OECTs) are essential in bioelectronics and printed electronics applications due to their simple structure, ease of tunability, biocompatibility, and suitability for different fabrication routes. This study presents a hybrid direct-write additive manufacturing approach to fabricating OECTs, combining 3D printing of conducting and insulating layers with inkjet printing of semiconducting thin films. The results demonstrate that this manufacturing method can rapidly produce OECTs and neuromorphic devices with good performance.
Organic electrochemical transistors (OECTs) are proving essential in bioelectronics and printed electronics applications, with their simple structure, ease of tunability, biocompatibility, and suitability for different routes to fabrication. OECTs are also being explored as neuromorphic devices, where they emulate characteristics of biological neural networks through co-location of information storage and processing on the same unit, overcoming the von Neumann performance bottleneck. To achieve the long-term vision of translating to inexpensive, low-power computational devices, fabrication needs to be feasible with adaptable, scalable digital techniques. Here, a hybrid direct-write additive manufacturing approach to fabricating OECTs is shown. 3D printing of commercially available printing filament is combined to deliver conducting and insulating layers, with inkjet printing of semiconducting thin films to create OECTs. These printed OECTs show depletion mode operation paired-pulse depression behavior and evidence of adaptation to support their translation to neuromorphic devices. These results show that a hybrid of accessible and design-flexible AM techniques can be used to rapidly fabricate devices that exhibit good OECT and neuromorphic performances.
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