Stencil mask defined doctor blade printing of organic single crystal arrays for high-performance organic field-effect transistors

Organic field-effect transistors (OFETs) are one of the promising candidates for next generation electronics due to their solution processability and good performance superior to amorphous Si devices. Patterning the organic layer is necessary in practical applications to prevent cross talk between different devices. Here, we reported a novel solution processed, high-resolution patterning method named as stencil mask defined doctor blade printing to fabricate regularly patterned organic single crystal arrays. The size of one pattern is around 30 mu m, which is smaller than the droplet diameter of conventional inkjet printing. The OFETs based on organic single crystal patterns exhibit extremely low off-state current and high on/off current ratio close to 10(10) as well as good device uniformity. The low off-state current demonstrates the potential of the OFET array for low-power or high-performance optical sensing applications. In addition, the short channel OFET array exhibits good frequency response operating at 20 kHz. This work provides an effective patterning strategy to realize solution processed large-area, high-resolution organic single crystal arrays.

Automated summary

Organic field-effect transistors are fabricated with high-resolution organic single crystal arrays using a novel patterning method, demonstrating low off-state current, high on/off current ratio, and good device uniformity. These devices show potential for low-power or high-performance optical sensing applications and exhibit good frequency response at 20 kHz.