Nature Communications (Feb 2024)

Synergistic-potential engineering enables high-efficiency graphene photodetectors for near- to mid-infrared light

  • Hao Jiang,
  • Jintao Fu,
  • Jingxuan Wei,
  • Shaojuan Li,
  • Changbin Nie,
  • Feiying Sun,
  • Qing Yang Steve Wu,
  • Mingxiu Liu,
  • Zhaogang Dong,
  • Xingzhan Wei,
  • Weibo Gao,
  • Cheng-Wei Qiu

DOI
https://doi.org/10.1038/s41467-024-45498-3
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 9

Abstract

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Abstract High quantum efficiency and wide-band detection capability are the major thrusts of infrared sensing technology. However, bulk materials with high efficiency have consistently encountered challenges in integration and operational complexity. Meanwhile, two-dimensional (2D) semimetal materials with unique zero-bandgap structures are constrained by the bottleneck of intrinsic quantum efficiency. Here, we report a near-mid infrared ultra-miniaturized graphene photodetector with configurable 2D potential well. The 2D potential well constructed by dielectric structures can spatially (laterally and vertically) produce a strong trapping force on the photogenerated carriers in graphene and inhibit their recombination, thereby improving the external quantum efficiency (EQE) and photogain of the device with wavelength-immunity, which enable a high responsivity of 0.2 A/W–38 A/W across a broad infrared detection band from 1.55 to 11 µm. Thereafter, a room-temperature detectivity approaching 1 × 109 cm Hz1/2 W−1 is obtained under blackbody radiation. Furthermore, a synergistic effect of electric and light field in the 2D potential well enables high-efficiency polarization-sensitive detection at tunable wavelengths. Our strategy opens up alternative possibilities for easy fabrication, high-performance and multifunctional infrared photodetectors.