Abstract
Selenium, depending on its crystal structure, can exhibit various properties and, as a result, be used in a wide range of applications. However, its exploitation has been limited due to the lack of understanding of its complex growth mechanism. In this work, template-free electrodeposition has been utilized for the first time to synthesize hexagonal-selenium (t-Se) microstructures of various morphologies at 80°C. Cyclic voltammetry (CV) and linear sweep voltammetry (LSV) revealed 5 reduction peaks, which were correlated with possible electrochemical or chemical reaction related to the formation of selenium. Potentiostatic electrodeposition using 100 mM SeO2 showed selenium nanorods formed at−0.389 V then increased in diameter up to −0.490 V, while more negative potentials (-0.594 V) induced formation of sub-micron wires with average diameter of 708 ± 116 nm. Submicron tubes of average diameter 744 ± 130 nm were deposited at −0.696 V. Finally, a mixture of tubes, wires, and particles was observed at more cathodic potential due to a combination of nucleation, growth, dissolution of structures as well as formation of amorphous selenium via comproportionation reaction. Texture coefficient as a function of applied potential described the preferred orientation of the sub-microstructures changed from (100) direction to more randomly oriented as more cathodic potentials were applied. Lower selenium precursor concentration lead to formation of nanowires only with smaller average diameters (124 ± 42 nm using 1 mM, 153 ± 46 nm using 10 mM SeO2 at −0.389 V). Time-dependent electrodeposition using 100 mM selenium precursor at −0.696 V explained selenium was formed first as amorphous, on top of which nucleation continued to form rods and wires, followed by preferential dissolution of the wire core to form tubes.
Highlights
Chalcogen microstructures are of great research interest due to their broad range of applications, such as optoelectronics (Qin et al, 2017), gas sensors (Tsiulyanu et al, 2001), medicine, energy harvesting, piezoelectrics (Lee et al, 2013), etc
The complex electrochemistry of selenium was systematically investigated using a series of electroanalytical studies and was determined to be dependent on the precursor concentration in the electrolyte
T-Se structures of various morphologies was achieved by electrodeposition without the aid of any template
Summary
Chalcogen microstructures are of great research interest due to their broad range of applications, such as optoelectronics (Qin et al, 2017), gas sensors (Tsiulyanu et al, 2001), medicine, energy harvesting, piezoelectrics (Lee et al, 2013), etc. Hexagonal selenium has high photoconductivity (e.g., 8 × 104 S cm−1) (Chen et al, 2009), a low melting point (217◦C) (Chen et al, 2009), non-linear optical properties due to its anisotropic crystal structure (Steichen and Dale, 2011), high piezoelectricity (d11 = 65 × 10−11 C/N)(Mayers et al, 2003), catalytic activity toward organic hydration and oxidation reactions (Xiong et al, 2006), and high reactivity leading to so many functional materials including Ag2Se (Tian et al, 2017), CdSe (Jeong et al, 2005; Sobhani and Salavati-Niasari, 2014), ZnSe (Zhang et al, 2016), PbSe (Salavati-Niasari et al, 2013), SnSe (Zhao et al, 2014), and NiSe (Salavati-Niasari and Sobhani, 2013; Hussain and Hussain, 2019) Such properties make Se a promising candidate for applications in photocells, photographic exposure meters, solar cells, semiconducting rectifiers, xerographic copying machines (Zhu and Hu, 2004), gas sensors (Norio and Tsukio, 2011) and Li-Se batteries (Gu et al, 2018). The diameter of the structures was measured from the SEM images utilizing the ImageJ software (30 structures were measured for each SEM image related to every sample)
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