Litcius/Paper detail

Tuning optical and electronic properties of 2D ZnI2/CdS heterostructure by biaxial strains for optical nanodevices: A first-principles study

Mohammed Jassim Abdulameer, Shurooq Sabah Abed Al-Abbas, Hamad Rahman Jappor

2021Journal of Applied Physics66 citationsDOI

Abstract

The structural and optoelectronic properties of a novel ZnI2/CdS van der Waals (vdW) heterostructure are studied under the effect of biaxial strain based on the density functional theory. Our results show that the ZnI2/CdS vdW heterostructure is dynamically and thermally stable depending on the molecular dynamics simulation and phonon dispersion curve. The results also indicate that the ZnI2/CdS heterostructure exhibits type-II band alignment with an indirect energy gap of 0.886 and 1.336 eV according to the Perdew–Burke–Ernzerhof and Heyd–Scuseria–Ernzerhof methods, respectively. Besides, the biaxial strain has a significant impact on the electronic properties. The energy bandgap of the ZnI2/CdS heterostructure decreases gradually as the compressive strain increases, reaching a minimum value of 1.162 eV at −6%. Also, a transformation from indirect bandgap to direct bandgap appears at strains of 4% and 6%. Broadly, it has been found that the optical properties of the ZnI2/CdS vdW heterostructure improve under the influence of strain, and the absorption coefficient can reach 105 cm−1 with the emergence of a shift phenomenon that expands the absorption capacity. Therefore, the application of strain will drastically improve the optical and electronic properties of the ZnI2/CdS vdW heterostructure, providing a roadmap for enhancing optical efficiency in photocatalytic and photovoltaic devices.

Topics & Concepts

HeterojunctionMaterials scienceBand gapvan der Waals forceDirect and indirect band gapsOptoelectronicsPhononCondensed matter physicsElectronic band structureAbsorption (acoustics)Density functional theoryChemistryComputational chemistryComposite materialPhysicsMoleculeOrganic chemistry2D Materials and ApplicationsMXene and MAX Phase MaterialsBoron and Carbon Nanomaterials Research