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Título : | Optical Properties of Reactive RF Magnetron Sputtered Polycrystalline Cu3N Thin Films Determined by UV/Visible/NIR Spectroscopic Ellipsometry: An Eco-Friendly Solar Light Absorber |
Autor : | Márquez, E. Blanco, E. García-Gurrea, M. Cintado Puerta, M. Domínguez de la Vega, M. Ballester, M. Mánuel, J.M. Rodríguez-Tapiador, M.I. Fernández, S. |
Palabras clave : | copper nitride semiconductor RF magnetron sputtering spectroscopic ellipsometry |
Fecha de publicación : | 25-jun-2023 |
Editorial : | Octavian Buiu |
Citación : | Márquez, E.; Blanco, E.; García-Gurrea, M.; Cintado Puerta, M.; Domínguez de la Vega, M.; Ballester, M.; Mánuel, J.M.; Rodríguez-Tapiador, M.I.; Fernández, S.M. Optical Properties of Reactive RF Magnetron Sputtered Polycrystalline Cu3N Thin Films Determined by UV/Visible/NIR Spectroscopic Ellipsometry: An Eco-Friendly Solar Light Absorber. Coatings 2023, 13, 1148. https:// doi.org/10.3390/coatings13071148 |
Citación : | volume;13 |
Resumen : | Copper nitride (Cu3N), a metastable poly-crystalline semiconductor material with reasonably high stability at room temperature, is receiving much attention as a very promising nextgeneration, earth-abundant, thin film solar light absorber. Its non-toxicity, on the other hand, makes it
a very attractive eco-friendly (greener from an environmental standpoint) semiconducting material.
In the present investigation, Cu3N thin films were successfully grown by employing reactive radiofrequency magnetron sputtering at room temperature with an RF-power of 50 W, total working gas
pressure of 0.5 Pa, and partial nitrogen pressures of 0.8 and 1.0, respectively, onto glass substrates.
We investigated how argon affected the optical properties of the thin films of Cu3N, with the aim of
achieving a low-cost solar light absorber material with the essential characteristics that are needed to
replace the more common silicon that is currently in present solar cells. Variable angle spectroscopic
ellipsometry measurements were taken at three different angles, 50◦
, 60◦
, and 70◦
, to determine the
two ellipsometric parameters psi, ψ, and delta, ∆. The bulk planar Cu3N layer was characterized by
a one-dimensional graded index model together with the combination of a Tauc–Lorentz oscillator,
while a Bruggeman effective medium approximation model with a 50% air void was adopted in
order to account for the existing surface roughness layer. In addition, the optical properties, such
as the energy band gap, refractive index, extinction coefficient, and absorption coefficient, were all
accurately found to highlight the true potential of this particular material as a solar light absorber
within a photovoltaic device. The direct and indirect band gap energies were precisely computed, and
it was found that they fell within the useful energy ranges of 2.14–2.25 eV and 1.45–1.71 eV, respectively. The atomic structure, morphology, and chemical composition of the Cu3N thin films were
analyzed using X-ray diffraction, atomic force microscopy, and energy-dispersive X-ray spectroscopy,
respectively. The Cu3N thin layer thickness, profile texture, and surface topography of the Cu3N
material were characterized using scanning electron microscopy. |
URI : | http://documenta.ciemat.es/handle/123456789/3017 |
ISSN : | 2079-6412 |
Aparece en las colecciones: | Artículos de Energía
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