Abstract
The improvement of the performance of organic thin-film transistors is driven by novel materials and improved device engineering. Key developments are a continuous increase of the charge carrier mobility, a scale-down of transistor dimensions, and the reduction of contact resistance. Furthermore, new transistor designs such as vertical devices are introduced to benefit from drastically reduced channel length while keeping the effort for structuring moderate. Here, we show that a strong electrothermal feedback occurs in organic transistors, ultimately leading to output characteristics with regions of S-shaped negative differential resistance. For that purpose, we use an organic permeable-base transistor (OPBT) with outstanding current densities, where a strong and reproducible, non-linear electrothermal feedback is revealed. We derive an analytical description of the temperature dependent current-voltage behavior and offer a rapid investigation method for material systems, where a temperature-activated conductivity can be observed.
Highlights
Aluminum (Al), chrome (Cr), n-doped C60 (n-C60), intrinsic C60 (i-C60), native aluminum-oxide (AlOX)
The best performance is reached by using contact-doping at the top emitter electrode, strongly reducing the contact resistance, so that the on-state of these devices is mainly limited by the charge transport through the intrinsic layers[8,30]
Further improvements can be achieved by inserting insulating layers of thermally evaporated SiO in order to reduce the active area of these devices[32]
Summary
Aluminum (Al), chrome (Cr), n-doped C60 (n-C60), intrinsic (undoped) C60 (i-C60), native aluminum-oxide (AlOX). Additional insulating layers (SiO) are inserted for defining and down-scaling the active area. (b) The thermal imaging during the S-NDR measurement confirms the increased temperature in the active area Aact of the OPBT. That purpose, we use an organic permeable-base transistor (OPBT) for which we recently reached current densities of 1 kA cm−2 8. A strong, reproducible, non-linear electrothermal feedback is revealed. We derive an analytical description of the temperature dependent current-voltage behavior, and check whether independently measured activation energies of the electrical conductivity can explain the experiment. We discuss the prospects which arise due to the strongly temperature activated conductivity
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