Abstract
Organic printed electronics has proven its potential as an essential enabler for applications related to healthcare, entertainment, energy, and distributed intelligent objects. The possibility of exploiting solution‐based and direct‐writing production schemes further boosts the benefits offered by such technology, facilitating the implementation of cheap, conformable, bio‐compatible electronic applications. The result shown in this work challenges the widespread assumption that such class of electronic devices is relegated to low‐frequency operation, owing to the limited charge mobility of the materials and to the low spatial resolution achievable with conventional printing techniques. Here, it is shown that solution‐processed and direct‐written organic field‐effect transistors can be carefully designed and fabricated so to achieve a maximum transition frequency of 160 MHz, unlocking an operational range that was not available before for organics. Such range was believed to be only accessible with more performing classes of semiconductor materials and/or more expensive fabrication schemes. The present achievement opens a route for cost‐ and energy‐efficient manufacturability of flexible and conformable electronics with wireless‐communication capabilities.
Highlights
The development of new applications in the fields of healthcare, energy, distributed sensing and entertainment will require the integration of electronic functionalities into everyday objects
We realized high-frequency Organic FieldEffect Transistor (OFET) in a bottom-contact, top-gate architecture with the layout schematized in Figure 1a, carefully selecting the architecture, materials and processes in order to overcome a variety of limitations to high-frequency operation
Contrarily to the widespread assumption that organic electronics is relegated to very lowfrequency operation, we have shown here that organic FETs can operate at an ft of 160 MHz and ft/V of 4 MHz V-1
Summary
The development of new applications in the fields of healthcare, energy, distributed sensing and entertainment will require the integration of electronic functionalities into everyday objects. Wireless communication between distributed electronic sensors/actuators and data-processing devices, or fast addressing capabilities for large-area arrays of sensors or light-emitting devices. The implementation of these functionalities would enable flexible large-area displays or sensor arrays and the creation of distributed wireless networks of electronic devices within the Internet of Things (IoT) framework.[14] So far, this set of applications has been considered out of reach for organic electronics
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