The Optical Properties of Sub-micrometer WS2 Preparing Using Electrochemical Fabrication

Journal of Measurements, Electronics, Communications, and Systems Pub Date : 2022-06-30 DOI:10.25124/jmecs.v9i1.5307

F. Pratama, I. P. Handayani, E. Wibowo

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Abstract

Photonic band gap tunability is crucial in designing optoelectronic devices. Nanostructure semiconductors with tunable band gaps which depend on the dimensionality, have become the potential candidate for tunable nano optoelectronic devices. However, it has a lot of challenges in their fabrication such as the limited number of homogenous particles and high-cost production. As an alternative, sub-micrometer particles with the order of hundred nanometers are more easily fabricated and exhibit tunable optoelectronic properties. In this study, sub-micrometer WS2 was fabricated using low-cost electrochemical methods. Two clusters of particles with the average size of 100 nm and 600 nm are observed. The number of sub-micrometer particles increases with the increasing of fabrication time. The photoluminescence spectra show wide peak centered around 800 nm suggesting the possible application in visible light emitting devices. The peak position varies with the time variation showing that the optical properties might be tuned during fabrication. This study points out that simple solution processed fabrication method can produce sub micrometer particles with tunable optical properties.

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电化学制备亚微米WS2的光学性质

光子带隙可调性是光电器件设计的关键。具有可调带隙的纳米结构半导体已成为可调纳米光电器件的潜在候选材料。然而，它在制造过程中面临着许多挑战，如均匀颗粒数量有限和生产成本高。作为替代方案，百纳米量级的亚微米粒子更容易制造，并表现出可调谐的光电特性。在本研究中，采用低成本的电化学方法制备了亚微米WS2。观察到两个平均粒径为100 nm和600 nm的颗粒团簇。随着制备时间的延长，亚微米颗粒的数量增加。光致发光光谱显示出800 nm左右的宽峰，表明该材料在可见光发射器件中的应用前景。峰值位置随时间的变化而变化，表明在制造过程中光学特性可能被调谐。本研究指出，简单的溶液加工方法可以制备出光学性能可调的亚微米粒子。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Measurements, Electronics, Communications, and Systems

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