Determination of structural and optical parameters of CuO thin films prepared by double dip technique

Shrividhya, T.; Ravi, G.; Hayakawa, Y.; Mahalingam, T.

doi:10.1007/s10854-014-2103-z

Cited by 43 publications

(18 citation statements)

References 30 publications

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“…The diffraction peaks presented at 2h = 35.584 and 38.772 corresponds to (002) and (200) planes of monoclinic CuO; it is in good agreement with the reported JCPDS data [39-0354]. Similar results of CuO have also been reported in the literature [32,33]. It is found to show an increase in diffraction peaks with the increase in copper salt concentration in the bath, and this increase in peak with copper concentration can be attributed to the increase in crystallinity of CuO films at increased concentration of copper ions.…”

Section: Experimental Methodssupporting

confidence: 90%

“…In this work, three Raman-active optical phonons have been identified and they are comparable to the earlier reports found in the literature, where different techniques were used to prepare CuO thin film [32]. This Raman analysis of the CuO sample confirms that the three known bands at 297, 345 and 631 cm -1 corresponds to Ag (297 cm -1 ), Bg (1) (341 cm -1 ) and Bg (2) (628 cm -1 ), respectively, which is in good agreement with the previously reported data [32]. And also it confirms that no Cu 2 O modes are presented in the CuO nanostructures prepared by us.…”

Section: Optical Analysissupporting

confidence: 87%

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Effect of bath concentration on the growth and photovoltaic response of SILAR-deposited CuO thin films

Visalakshi

Kannan

Valanarasu³

et al. 2015

Appl. Phys. A

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Solar cell property of p-CuO/n-Si heterojunction was investigated using SILAR-deposited CuO thin films. The effects of copper salt concentration on the growth of CuO films and its effect on the efficiency in solar cell conversion were investigated. Structural, morphological, optical and electrical studies of the CuO thin films deposited at 90°C with different copper sulphate concentrations are reported. Crystallinity of the film is found to increase with the increase in copper sulphate concentration. The measured Raman spectrum of the deposited film showed peaks corresponding to CuO phase. It is observed by the SEM that the film is homogeneous fully covering the substrate. The optical band gap of the deposited film has exhibited a decrease in band gap from 1.76 to 1.57 eV with the increase in copper sulphate concentration. Solar cell device was constructed using the p-CuO film deposited on n-silicon substrate, and its photovoltaic response was measured. It showed increasing photoresponse with increasing concentration of copper sulphate.

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Section: Experimental Methodssupporting

confidence: 90%

Section: Optical Analysissupporting

confidence: 87%

Effect of bath concentration on the growth and photovoltaic response of SILAR-deposited CuO thin films

Visalakshi

Kannan

Valanarasu³

et al. 2015

Appl. Phys. A

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“…The three Raman peaks obtained at 295, 343 and 628 cm -1 can be assigned to one A g and two B g modes, respectively. This observation has an agreement with the previous reports [18]. Figure 3 shows the scanning electron micrograph (SEM) of SILAR deposited CuO thin films prepared at different adsorption times.…”

Section: Experiments Proceduressupporting

confidence: 91%

Effect of adsorption time on structural, optical and electronic properties of SILAR deposited CuO thin films

Visalakshi

Kannan

Valanarasu³

et al. 2016

J Mater Sci: Mater Electron

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Deposition of CuO thin films onto glass substrates by SILAR technique changing the adsorption time is reported. Adsorption time dependent variation on structural, optical and electric properties of the films has been analyzed. X-ray diffraction (XRD) pattern of the films have confirmed the polycrystalline monoclinic structure with (002) preferred orientation. Intensity of the XRD peaks is found to increase with the increase of adsorption time. Crystallite size, lattice parameters, defect density and texture coefficient of the film have been calculated using the XRD data. Surface morphology studies of the films done by scanning electron microscopy showed uniform and continuous film with spherical particles. Optical absorption studies of the films have revealed that the optical band gap of the thin films is decreased with the increase of adsorption time and it lies between 2.12-1.91 eV. Hall Effect measurements of the films have shown that the obtained material has p-type conductivity and resistivity values are found to decrease with adsorption time. I-V property of the fabricated p-CuO/n-Si diode has been measured by illuminating the device with a halogen lamp of intensity 200 W and it has shown a maximum open circuit voltage (V oc ) 0.05 V and short-circuit current (I sc ) 0.25 9 10 -6 A.

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“…The latter has affected oxygen diffusion, interfacial strain due to the difference in thermal expansion coefficients[35]. The initial stage of copper oxidation in thin film is the oxygen surface diffusion which is the dominant mechanism [36,37] and had eminent role in the kinetics of the oxidation stage[38].…”

mentioning

confidence: 99%

Structural and optical characterization of copper oxide composite thin films elaborated by GLAD technique

Tounsi

Barhoumi

Akkari

et al. 2015

Vacuum

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Determination of structural and optical parameters of CuO thin films prepared by double dip technique

Cited by 43 publications

References 30 publications

Effect of bath concentration on the growth and photovoltaic response of SILAR-deposited CuO thin films

Effect of bath concentration on the growth and photovoltaic response of SILAR-deposited CuO thin films

Effect of adsorption time on structural, optical and electronic properties of SILAR deposited CuO thin films

Structural and optical characterization of copper oxide composite thin films elaborated by GLAD technique

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