Optimization of erbium percentage molarity on cobalt selenide semiconductor material via spray pyrolysis deposition technique for photovoltaic application

The spray pyrolysis approach was used to successfully synthesize cobalt selenide (CoSe) and cobalt selenide doped erbium (CoSe/Er) materials. The XRD patterns of cobalt selenide (CoSe) and cobalt selenide doped erbium (CoSe/Er) semiconductor materials show strong crystalline peaks at 2θ = 16.03°, 20...

Full description

Saved in:
Bibliographic Details
Published in:Journal of the Indian Chemical Society 2022-12, Vol.99 (12), p.100793, Article 100793
Main Authors: Ikhioya, Imosobomeh L., Udeze, C.U., Ochai-Ejeh, Faith U., Ahmed, Ishaq, Maaza, M., Ezema, Fabian I.
Format: Article
Language:English
Subjects:
Cobalt selenide
Erbium
Rare-earth ion
Spray pyrolysis
Thin-film
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The spray pyrolysis approach was used to successfully synthesize cobalt selenide (CoSe) and cobalt selenide doped erbium (CoSe/Er) materials. The XRD patterns of cobalt selenide (CoSe) and cobalt selenide doped erbium (CoSe/Er) semiconductor materials show strong crystalline peaks at 2θ = 16.03°, 20.29°, 23.89°, 31.92°, and 41.32°, corresponding to diffraction planes (110), (111), (200), (203), and (220). The formation of cobalt selenide material can be determined from the X-ray spectrum angle 16.03°, which corresponds to diffraction plane (110) while the remaining 2 theta angles and diffraction peak demonstrate the formation of cobalt selenide doped erbium. The average size of the crystallites was calculated to be 55.08 nm. Surface morphology analyses indicated homogenous flat nanocrystals at low doping concentrations and massive nanocrystal clusters as doping concentrations increased. The transmittance spectra show that the transmittance of both the CoSe and the Er-doped CoSe thin films significantly increases below 400 nm. The estimated direct bandgap, which is in the 1.53–2.01 eV range and rises with concentration due to a strong quantum effect, makes it appropriate for use in photovoltaic cells. [Display omitted] •Successful deposition and characterization of CoSe and erbium doped CoSe films.•The prepared cobalt selenide and cobalt selenide doped erbium are polycrystalline.•Surface micrograph of the prepared cobalt selenide and cobalt selenide doped erbium concede homogeneous flat nanocrystals at lower doping concentration and large nanoclustered•The energy bandgap for the deposited material was found to range from and 1.53–2.01 eV.
ISSN:0019-4522
DOI:10.1016/j.jics.2022.100793