Yang Wang scite author profile

With the increasing demand for multispectral information acquisition, infrared multispectral imaging technology that is inexpensive and can be miniaturized and integrated into other devices has received extensive attention. However, the widespread usage of such photodetectors is still limited by the high cost of epitaxial semiconductors and complex cryogenic cooling systems. Here, we demonstrate a noncooled two-color infrared photodetector that can provide temporal-spatial coexisting spectral blackbody detection at both near-infrared and mid-infrared wavelengths. This photodetector consists of vertically stacked back-to-back diode structures. The two-color signals can be effectively separated to achieve ultralow crosstalk of ~0.05% by controlling the built-in electric field depending on the intermediate layer, which acts as an electron-collecting layer and hole-blocking barrier. The impressive performance of the two-color photodetector is verified by the specific detectivity (D*) of 6.4 × 109 cm Hz1/2 W−1 at 3.5 μm and room temperature, as well as the promising NIR/MWIR two-color infrared imaging and absolute temperature detection.

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Ultrabroadband Photodetectors up to 10.6 µm Based on 2D Fe₃O₄ Nanosheets

Yin

Gong

Chu

et al. 2020

Advanced Materials

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The ultrabroadband spectrum detection from ultraviolet (UV) to long‐wavelength infrared (LWIR) is promising for diversified optoelectronic applications of imaging, sensing, and communication. However, the current LWIR‐detecting devices suffer from low photoresponsivity, high cost, and cryogenic environment. Herein, a high‐performance ultrabroadband photodetector is demonstrated with detecting range from UV to LWIR based on air‐stable nonlayered ultrathin Fe3O4 nanosheets synthesized via a space‐confined chemical vapor deposition (CVD) method. Ultrahigh photoresponsivity (R) of 561.2 A W−1, external quantum efficiency (EQE) of 6.6 × 103%, and detectivity (D*) of 7.42 × 108 Jones are achieved at the wavelength of 10.6 µm. The multimechanism synergistic effect of photoconductive effect and bolometric effect demonstrates the high sensitivity for light with any light intensities. The outstanding device performance and complementary mixing photoresponse mechanisms open up new potential applications of nonlayered 2D materials for future infrared optoelectronic devices.

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Breaking the Rate-Loss Bound of Quantum Key Distribution with Asynchronous Two-Photon Interference

et al. 2022

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Yang Wang

Fast and practical secret key extraction by exploiting channel response

Van der Waals two-color infrared photodetector

Ultrabroadband Photodetectors up to 10.6 µm Based on 2D Fe₃O₄ Nanosheets

Breaking the Rate-Loss Bound of Quantum Key Distribution with Asynchronous Two-Photon Interference

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About

Yang Wang

Fast and practical secret key extraction by exploiting channel response

Van der Waals two-color infrared photodetector

Ultrabroadband Photodetectors up to 10.6 µm Based on 2D Fe3O4 Nanosheets

Breaking the Rate-Loss Bound of Quantum Key Distribution with Asynchronous Two-Photon Interference

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Product

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Ultrabroadband Photodetectors up to 10.6 µm Based on 2D Fe₃O₄ Nanosheets