Formation mechanism, stability and role of zinc and sulfur vacancies on the electronic properties and optical response of ZnS

TL;DR

This study combines experimental and theoretical methods to show that zinc vacancies in ZnS significantly influence its electronic and optical properties, enabling potential optoelectronic applications.

Contribution

It provides new insights into how zinc vacancies alter ZnS's optical response, supported by combined experimental and first-principles theoretical analysis.

Findings

Zn vacancies induce semiconducting behavior in ZnS surface

Defective ZnS shows visible-range absorption peaks

Zinc vacancies enable tuning of optical properties for optoelectronic devices

Abstract

Combining experimental and theoretical tools, we report that Zn vacanciesplay an important role in the electronic and optical responses of ZnS sphalerite. The defective surface of ZnS (001) single crystal prepared in ultra-highvacuum conditions, has been shown to exhibit a semiconducting character instead of the insulating properties of the pristine structure, as revealed by X-ray photoelectron spectroscopy (XPS). Interestingly, this effect is attributed to the formation of zinc vacancies in the ZnS system, which also alter the optical response of the material, as supported by photoluminescence (PL) measurements comparing pristine and S-rich (Zn-poor) ZnS. To address these findings from a theoretical point of view, first principles calculations based on density functional theory (DFT) were performed. The optical properties of cation-defective ZnS were evaluated using random-phase approximation and hybrid functional DFT calculations. These calculations revealed absorption peaks in the visible range in the defective ZnS rather than solely in the ultra-violet range obtained for defect-free ZnS. The combination of this finding with joint density of states (JDOS) analysis explains the emergence of new luminescence peaks observed in the PL spectra of cation-defective ZnS. These findings highlight the role of Zn vacancies in tuning ZnS optical properties, making it a potential candidate for optoelectronic applications such as LEDs and photodetectors.