First‐Principle Study of Bandgap Engineering and Optical Properties of Monolayer WSe<sub>2</sub> in Second Near‐Infrared Windows
Ruoli Zhao, Ling Liu, Jiahui Pei, Changlong Liu, Tianyu Liu, Xiaodong Zhang
Abstract
Abstract Fluorescence imaging in the second near‐infrared II (NIR‐II) window is opening up new possibilities in bioimaging due to its low scattering rate within the tissue. The integration of 2D materials with NIR‐II fluorescence will enable the development of multifunctional imaging probes. However, there are very few 2D materials that can fluoresce in the NIR‐II range. Monolayer WSe 2 is a potential 2D material, but its photoluminescence (PL) around 790 nm is still far from the NIR‐II range due to its bandgap of 1.54 eV. In this study, it is investigated the electronic structures, dielectric functions, and PL spectra for Te, I, and Cr‐doped monolayer WSe 2 , as well as W and S vacant monolayer WSe 2 . Most of the defected monolayer WSe 2 remain semiconductors, except for a few configurations exhibiting metallic properties after making vacancies. Among the monolayer WSe 2 under investigation, the Cr‐doped WSe 2 performs the best, exhibiting a strong PL peak in NIR‐II with a decreased bandgap around 1.0 eV. As increasing Cr concentration, the peak shifts further toward the red end of the spectrum due to an enhancement of p–d transition. The results provide a useful guideline for material synthesis applied in NIR‐II bioimaging and other biophysics.