Ultrathin and Ultrasensitive Direct X‐ray Detector Based on Heterojunction Phototransistors
Yuanhong Gao, Yongshuai Ge, Xinwei Wang, Jin Liu, Wenquan Liu, Yong Cao, Kaichen Gu, Zheng Guo, Yuming Wei, Ni Zhou, De Yu, Hong Meng, Xue‐Feng Yu, Hairong Zheng, Wei Huang, Jia Li
Abstract
Abstract Most contemporary X‐ray detectors adopt device structures with non/low‐gain energy conversion, such that a fairly thick X‐ray photoconductor or scintillator is required to generate sufficient X‐ray‐induced charges, and thus numerous merits for thin devices, such as mechanical flexibility and high spatial resolution, have to be compromised. This dilemma is overcome by adopting a new high‐gain device concept of a heterojunction X‐ray phototransistor. In contrast to conventional detectors, X‐ray phototransistors allow both electrical gating and photodoping for effective carrier‐density modulation, leading to high photoconductive gain and low noise. As a result, ultrahigh sensitivities of over 10 5 μC Gy air −1 cm −2 with low detection limit are achieved by just using an ≈50 nm thin photoconductor. The employment of ultrathin photoconductors also endows the detectors with superior flexibility and high imaging resolution. This concept offers great promise in realizing well‐balanced detection performance, mechanical flexibility, integration, and cost for next‐generation X‐ray detectors.