Litcius/Paper detail

Carrier‐Transport Mechanism in Organic Antiambipolar Transistors Unveiled by Operando Photoemission Electron Microscopy

Ryoma Hayakawa, Soichiro Takeiri, Y. Yamada, Yutaka Wakayama, Keiki Fukumoto

2022Advanced Materials21 citationsDOIOpen Access PDF

Abstract

Organic antiambipolar transistors (AATs) have partially overlapped p-n junctions. At room temperature, this p-n junction induces a negative differential transconductance in an AAT. However, the detailed carrier-transport mechanism remains unclear. Herein, an operando photoemission electron microscopy is used to tackle this issue owing to the technique's ability to visualize conductive electrons in real time during transistor operation. Notably, it is observed that when the AAT is on, a depletion layer forms at the lateral p-n junction. The visualized depletion layer shows that both p- and n-type channels have pinch-off states in the gate voltage range when the AAT is in on state. The steep potential gradient at the lateral p-n interface enhances the electron conduction from n-type to p-type semiconductor. Another significant finding is that most electrons are considered to recombine with the accumulated holes in the p-type semiconductor, affording the reduction of photoemission intensity by ≈80%. This technique provides a thorough understanding of carrier transport in AATs, further improving the device performance.

Topics & Concepts

Materials scienceSemiconductorElectronTransconductanceTransistorOptoelectronicsDepletion regionPhotoemission electron microscopyOrganic semiconductorNanotechnologyElectron microscopeVoltageElectrical engineeringPhysicsOpticsEngineeringQuantum mechanicsOrganic Electronics and PhotovoltaicsThermal properties of materialsConducting polymers and applications