Unraveling essential optoelectronic and thermoelectric excellence in CsZrCuSe3 with hybrid functional and Boltzmann transport insights

[Display omitted] •Exploring CsZrCuSe3’s optoelectronic properties using DFT and Boltzmann theory.•Tunable bandgap makes CsZrCuSe3 promising for photodetectors and solar cells.•Direct bandgap of 1.32 eV at the Γ point revealed in electronic property study.•Optical analysis shows strong violet-blue a...

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Bibliographic Details
Published in:Results in physics 2024-02, Vol.57, p.107395, Article 107395
Main Authors: Goumri-Said, Souraya, Alshoaibi, Adil, Azam, Sikander, Khenata, Rabah, Ul Haq, Bakhtiar, Rahman, Md. Ferdous, Kanoun, Mohammed Benali
Format: Article
Language:English
Subjects:
Density Functional Theory (DFT)
Figure of merit (ZT)
Optoelectronic properties
Quaternary chalcogenide (CsZrCuSe3)
Thermoelectric properties
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Summary:[Display omitted] •Exploring CsZrCuSe3’s optoelectronic properties using DFT and Boltzmann theory.•Tunable bandgap makes CsZrCuSe3 promising for photodetectors and solar cells.•Direct bandgap of 1.32 eV at the Γ point revealed in electronic property study.•Optical analysis shows strong violet-blue absorption, with dielectric constant insights.•Exploring thermoelectric behavior, Seebeck anomalies, and applications in tech advancements. This research paper delves into the optoelectronic and thermoelectric properties of the quaternary layered selenide compound CsZrCuSe3, employing a comprehensive computational approach based on density functional theory (DFT) with the HSE06 functional and Boltzmann transport theory. CsZrCuSe3 is a quaternary chalcogenide compound with a tunable bandgap, making it a promising candidate for optoelectronic applications such as photodetectors, solar cells, and LEDs. The electronic properties of CsZrCuSe3 were investigated, revealing a direct bandgap of 1.32 eV at the Γ point. The optical properties, including the dielectric constant and optical conductivity, were analyzed, demonstrating strong absorption in the violet-blue range. Furthermore, the paper explores the thermoelectric properties of CsZrCuSe3, including the Seebeck coefficient, electrical conductivity, thermal conductivity, and the figure of merit (ZT). These properties exhibit intriguing behavior dependent on temperature and chemical potential, with an anomaly observed in the Seebeck coefficient at specific chemical potentials. This anomaly presents an opportunity to gain insights into the complex interplay of electronic properties in semiconductor materials, potentially leading to advancements in thermoelectric applications. Further research and collaboration are essential to decipher the underlying mechanisms and optimize the material for practical use in various technological applications.
ISSN:2211-3797
2211-3797
DOI:10.1016/j.rinp.2024.107395