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Tellurene Photodetector with High Gain and Wide Bandwidth.

Chenfei ShenYihang LiuJiangbin WuChi XuDingzhou CuiZhen LiQingzhou LiuYuanrui LiYixiu WangXuan CaoHiroyuki KumazoeFuyuki ShimojoAravind KrishnamoorthyRajiv K KaliaAiichiro NakanoPriya D VashishtaMor R AmerAhmad N AbbasHan WangWenzhuo WuChongwu Zhou
Published in: ACS nano (2020)
Two-dimensional (2D) semiconductors have been extensively explored as a new class of materials with great potential. In particular, black phosphorus (BP) has been considered to be a strong candidate for applications such as high-performance infrared photodetectors. However, the scalability of BP thin film is still a challenge, and its poor stability in the air has hampered the progress of the commercialization of BP devices. Herein, we report the use of hydrothermal-synthesized and air-stable 2D tellurene nanoflakes for broadband and ultrasensitive photodetection. The tellurene nanoflakes show high hole mobilities up to 458 cm2/V·s at ambient conditions, and the tellurene photodetector presents peak extrinsic responsivity of 383 A/W, 19.2 mA/W, and 18.9 mA/W at 520 nm, 1.55 μm, and 3.39 μm light wavelength, respectively. Because of the photogating effect, high gains up to 1.9 × 103 and 3.15 × 104 are obtained at 520 nm and 3.39 μm wavelength, respectively. At the communication wavelength of 1.55 μm, the tellurene photodetector exhibits an exceptionally high anisotropic behavior, and a large bandwidth of 37 MHz is obtained. The photodetection performance at different wavelength is further supported by the corresponding quantum molecular dynamics (QMD) simulations. Our approach has demonstrated the air-stable tellurene photodetectors that fully cover the short-wave infrared band with ultrafast photoresponse.
Keyphrases
  • molecular dynamics
  • photodynamic therapy
  • gold nanoparticles
  • density functional theory
  • risk assessment
  • quantum dots
  • light emitting
  • tandem mass spectrometry