AllâPhotolithography Fabrication of IonâGated Flexible Organic Transistor Array for Multimode Neuromorphic Computing
Abstract
Organic ionâgated transistors (OIGTs) demonstrate commendable performance for versatile neuromorphic systems. However, due to the fragility of organic materials to organic solvents, efficient and reliable allâphotolithography methods for scalable manufacturing of highâdensity OIGT arrays with multimode neuromorphic functions are still missing, especially when all active layers are patterned in highâdensity. Here, a flexible highâdensity (9662 devices per cm2) OIGT array with high yield and minim...
Description / Details
Organic ionâgated transistors (OIGTs) demonstrate commendable performance for versatile neuromorphic systems. However, due to the fragility of organic materials to organic solvents, efficient and reliable allâphotolithography methods for scalable manufacturing of highâdensity OIGT arrays with multimode neuromorphic functions are still missing, especially when all active layers are patterned in highâdensity. Here, a flexible highâdensity (9662 devices per cm2) OIGT array with high yield and minimal deviceâtoâdevice variation is fabricated by a modified allâphotolithography method. The unencapsulated flexible array can withstand 1000 timesâ bending at a radius of 1 mm, and 3 monthsâ storage test in air, without obvious performance degradation. More interesting, the OIGTs can be configured between volatile and nonvolatile modes, suitable for constructing reservoir computing systems to achieve high accuracy in classifying handwritten digits with low training costs. This work proposes a promising design of organic and flexible electronics for affordable neuromorphic systems, encompassing both array and algorithm aspects.
Source: Semantic Scholar - Advances in Materials (51 citations) PDF: N/A Original Link: https://www.semanticscholar.org/paper/529e63a6236b4c3ea94b048a4f5ffa4f7c2c3d2d
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Feb 15, 2026
Medicine
Peer Reviewed
0