Direct Tellurization of Pt to Synthesize 2D PtTe2 for High-Performance Broadband Photodetectors and NIR Image Sensors

Platinum telluride (PtTe2) has garnered significant research enthusiasm owing to its unique characteristics. However, large-scale synthesis of PtTe2 toward potential photoelectric and photovoltaic application has not been explored yet. Herein, we report direct tellurization of Pt nanofilms to synthesize large-area PtTe2 films and the influence of growth conditions on the morphology of PtTe2. Electrical analysis reveals that the as-grown PtTe2 films exhibit typical semimetallic behavior, which is in agreement with the results of first-principles density functional theory (DFT) simulation. Moreover, the combination of multilayered PtTe2 and Si results in the formation of a PtTe2/Si heterojunction, exhibiting an obvious rectifying effect. Moreover, the PtTe2-based photodetector displays a broadband photo- response to incident radiation in the range of 200-1650 nm, with the maximum photoresponse at a wavelength of -980 nm. The R and D* of the PtTe2-based photodetector are found to be 0.406 A W-1 and 3.62 X 10(12) Jones, respectively. In addition, the external quantum efficiency is as high as 32.1%. On the other hand, the response time of tau(rice) and tau(fall) is estimated to be 7.51 and 36.7 ps, respectively. Finally, an image sensor composed of a 8 X 8 PtTe2 based photodetector array was fabricated, which can record five near-infrared (NIR) images under 980 nm with a satisfying resolution. The result demonstrates that the as-prepared PtTe2 material will be useful for application in NIR optoelectronics.