ZrTe3/PdSe2 vis-NIR detectors with Schottky barrier enhanced photovoltaic performance
Infrared photodetectors (PDs), particularly the near-infrared (NIR) PDs, are essential for applications in remote sensing, night vision, imaging, and so on. ZrTe3, a semimetallic transition metal trichalcogenide with zero bandgap, strong anisotropy, and enhanced conductivity, is emerging as a promis...
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Veröffentlicht in: | Applied physics letters 2024-12, Vol.125 (25) |
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Hauptverfasser: | , , , , , , , , , , , |
Format: | Artikel |
Sprache: | eng |
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Zusammenfassung: | Infrared photodetectors (PDs), particularly the near-infrared (NIR) PDs, are essential for applications in remote sensing, night vision, imaging, and so on. ZrTe3, a semimetallic transition metal trichalcogenide with zero bandgap, strong anisotropy, and enhanced conductivity, is emerging as a promising material for NIR PDs, provided that the noise can be effectively suppressed. The solution lies in constructing an appropriate barrier. PdSe2, a typical two-dimensional material with a layer-dependent bandgap is an excellent choice. By constructing a VdW heterostructure with ZrTe3 and six-layer PdSe2, a Schottky barrier is introduced to block photogenerated holes in ZrTe3, resulting in a five-order-of-magnitude reduction in dark current and an enhanced photovoltaic response. The ZrTe3/PbSe2 PD exhibits a self-powered photovoltaic response from 405 nm to 1.55 μm with a peak responsivity of 1.16 × 106 V/W, a rise/fall time of 58/66 μs, a 3 dB frequency of 4.6 kHz, and a linear polarization ratio of 3.15 at 808 nm. The strategy of introducing a Schottky barrier to semimetal-based PDs addresses the issues of high noise and biased working conditions, paving the way for high-performance semimetallic PDs in the NIR range. |
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ISSN: | 0003-6951 1077-3118 |
DOI: | 10.1063/5.0237308 |