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Effect of Cu Interlayer on Opto-Electrical Parameters of Zno Thin Films

journal of material science :materiales in electronics • 2022
العودة
معلومات البحث
المؤلفون S. S. Fouad , B. Parditka , M. Nabil E. Barada ´ cs * , E. Barada, and Zolta ´ n Erde ´ cs 2,4 , S. Negm Department of Physics, Fac Cairo 11566, Egypt , and Zolta ´ n Erde ´ l
الكلمات المفتاحية Absorption, Roughness, Optical band gap, Refractive index.
المجلة العلمية journal of material science :materiales in electronics
الناشر springer
المجلد 33
العدد 26
الصفحات 20594-20603
publication.type International
رابط البحث Open Link
المواد المرفقة Not Available
الملخص
In this paper, we focused our attention on the tailoring of structure and optical
analysis as a function of Cu interlayer between the ZnO layers. The Cu interlayer
was deposited by magnetron sputtering, while the ZnO layers were
deposited by atomic layer deposition. Morphological analysis, based on grazing
incident X-ray diffraction patterns and scanning electron microscope images,
revealed formation of crystalline phase and a successful incorporation of Cu into
ZnO. The estimated average crystallite size increased from 8.64 to 12.05 nm as
Cu interlayer thickness increased from 20 to 70 nm. The averaged value of the
surface roughness was determined, from both the profilometer and the XRD
measurements. The determinations of the optical band gap and the nature of
optical transition were performed by the analysis of absorption spectrum. Also,
some physical quantities, such as optical density OD and skin depth d, were
estimated. Optical absorption studies revealed that all the films have a direct
allowed transition. A shift in the optical energy band gap E
from 2.75 to 2.43 eV
as a function of Cu interlayer thickness was observed. The linear refractive
index (n) was analyzed to determine the metallization criterion M, the reflection
loss function R
L
g
, the transmission coefficient T and the relative density D
.
Moreover, we showed that the doping of ZnO with different thickness of Cu
interlayer enhances its optical activity and electrical conductivity as well, which
makes it useful for photocatalytic application and sensor device fabrication in
particular conditions.