Investigation of morphological, optical and structural properties of multi-layer coatings for solar energy

The multi-layers of nanomaterials, for the time being, are materials of great significance in the field of nanoscience. In this work, some of the physical, morphological and structural properties of multi-coatings for solar energy applications have been studied. We investigated the impact of surface...

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Veröffentlicht in:	Applied physics. A, Materials science & processing Materials science & processing, 2020-04, Vol.126 (4), Article 275
1. Verfasser:	Gbashi, Kadhim R.
Format:	Artikel
Sprache:	eng
Schlagworte:	Applied physics Atomic force microscopy Characterization and Evaluation of Materials Coatings Condensed Matter Physics Crystal structure Crystallites Energy gap Investigations Machines Manufacturing Materials science Microscopy Morphology Multilayers Nanomaterials Nanotechnology Optical and Electronic Materials Optical properties Performance enhancement Physics Physics and Astronomy Processes Refractivity Solar energy Solar Energy Materials and Applications Surface roughness Surfaces and Interfaces T.C. : Solar Energy Materials and Applications Thin Films
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creator	Gbashi, Kadhim R.
description	The multi-layers of nanomaterials, for the time being, are materials of great significance in the field of nanoscience. In this work, some of the physical, morphological and structural properties of multi-coatings for solar energy applications have been studied. We investigated the impact of surface roughness with the number of layers on the optical and structural properties. Decreasing surface roughness led to improve performance of transmittance, reduce reflectance, and increase bandgap for single-, double-, triple-, and quadruple coatings of semiconductors. Moreover, the decreasing in crystallite size and changing in lattice parameter are due to more strain effect on peak broadening of the crystal structure. The experimental observations are supported by simulation based on the surface roughness with the energy gaps and refractive indices, and film morphology was studied by scanning force microscopy and scanning electron microscopy, optical properties studied by UV–visible spectroscopy and structural properties investigated by X-ray diffraction.
doi_str_mv	10.1007/s00339-020-3419-6
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subjects	Applied physics Atomic force microscopy Characterization and Evaluation of Materials Coatings Condensed Matter Physics Crystal structure Crystallites Energy gap Investigations Machines Manufacturing Materials science Microscopy Morphology Multilayers Nanomaterials Nanotechnology Optical and Electronic Materials Optical properties Performance enhancement Physics Physics and Astronomy Processes Refractivity Solar energy Solar Energy Materials and Applications Surface roughness Surfaces and Interfaces T.C. : Solar Energy Materials and Applications Thin Films
title	Investigation of morphological, optical and structural properties of multi-layer coatings for solar energy
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