Optical and structural characterization of CdSe:Eu films at different volumes of europium concentration.

Jeroh, Diemiruaye; Ekpunobi, Azubike; Okoli, Donald

doi:10.30495/jtap.162219

کد مقاله : JTAP-2203-1044 (R1) بازدید : 45 صفحه: 1 - 5

10.30495/jtap.162219

نوع مقاله: پژوهشی

Optical and structural characterization of CdSe:Eu films at different volumes of europium concentration.

محورهای موضوعی : Journal of Theoretical and Applied Physics

Diemiruaye Jeroh ¹ (Department of Physics, Nnamdi Azikiwe University, Awka, Nigeria.)
Azubike Ekpunobi ² (Department of Physics, Nnamdi Azikiwe University, Awka, Nigeria.)
Donald Okoli ³ (Department of Physics, Nnamdi Azikiwe University, Awka, Nigeria.)

تاریخ دریافت : 1400/12/25 تاریخ پذیرش : 1401/02/23 تاریخ انتشار : 1401/03/11

کلید واژه: Hexagonal, nanomaterials, Spray Pyrolysis, Electrostatic, Wurtzite,

چکیده مقاله :

Cadmium selenide films were prepared at different volumes of dopant (Europium) concentration by electrostatic-spray-pyrolysis technique. Optical results reveal low absorption and reflection with a corresponding high transmission in the visible region. Strong blue-shift is observed for the band gap energy in all cases of growth, indicating quantum confinement effect. Scanning electron studies reveal relatively smooth surface with small-sized grains on the surface. XRD confirms the crystalline nature of the films having hexagonal (wurtzite) structure with reduction in crystallinity of the film at increased volume of dopant concentration. EDX analysis confirmed the growth of CdSe:Eu film.

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Optical and Structural Characterization of CdSe:Eu Films at Different Volumes of Europium Concentration

*1Jeroh, D.M., 2Ekpunobi, A.J., 3Okoli, D.N.

1-3 Nnamdi Azikiwe University, Awka.

Email: dm.jeroh@unizik.edu.ng

Abstract

Keywords: Hexagonal, Wurtzite, Electrostatic, Spray pyrolysis, nanomaterials, Optical

Introduction

Semiconductor-based devices have proved useful in vast areas including solar cells fabrication, optical fibre communications, electronic device fabrication, etc. The study of semiconductors at the nanoscale has proved over the years that nanomaterials display unique characteristics different from the bulk phase. It is based on this premise that more research is done on nanomaterials to fully understand their functions. Semiconductor particles exhibit characteristics (change in optical properties and enhanced energy gap) that are dependent on size; hence they stand amongst the important technological materials [1].

Cadmium selenide (CdSe) fit into the II-VI class of semiconductors having eight (8) valence electrons. It has immense relevance in solar cells, optoelectronics and lasers. Europium (Eu) has nine (9) valence electrons and characterized by unique optical and photoluminescence properties. Regarding the properties exhibited by europium, it is expected that doping CdSe with Eu will produce a new material with improved functions.

CdSe has been previously synthesized by chemical process [1-4], electrodeposition [5] and thermal evaporation [6].

In the literature, few reports [7-9] on CdSe:Eu synthesis are available. This research focussed on CdSe:Eu synthesis by electrostatic-spray-pyrolysis at different volumes of Eu concentration, which is unavailable in previous literatures.

Experimental

The growth of CdSe:Eu by electrostatic-spray-pyrolysis has been reported [8]. Absorbance measurements were obtained via UV-VIS spectrophotometer in the wavelength range of 200 nm to 800 nm. Transmittance and reflectance were calculated from absorbance values. X-ray diffraction was performed by an X’pert pro x-ray diffractometer with scanning angles between 0o and 80o. Scanning electron microscopy (SEM) was executed using a Carl-Zeiss scanning electron microscope, while energy dispersive analysis x-ray spectroscopy was done using the facility fixed to the SEM equipment.

Results and Discusions

The optical, structural and EDX results are presented in this section and analyzed accordingly.

$C:\Users\Dr. E.J. Jeroh\Desktop\PhD Results\ABS CDEUSE.jpg$

Figure 1: Absorbance spectra of CdSe:Eu

The CdSe:Eu displayed poor absorption all through the UV and VIS regions. In the UV region, between 10% and 31% absorption is observed, while for the VIS region, between 0.1% and 10% is observed. The exhibited peaks in the absorption spectrum around 270 nm and 300 nm suggest the presence of defect states within the crystal lattice of CdSe:Eu. Such defects states are very vital in electronic transitions within the material. Due to the large dopant concentrations, states within the conduction band becomes populated, hence, pushing the absorption edge to higher energies and subsequently increases the band gap energy.

$C:\Users\Dr. E.J. Jeroh\Desktop\PhD Results\Transmittance CdEuSe.jpg$

Figure 2: Transmittance spectra of CdSe:Eu

The CdSe:Eu deposited at different dopant concentrations recorded low transmittance from 49.81% to 59.84% in the UV-region while the films have high transmittance between 73.08% to 97.63% in the VIS-region as shown in figure 2.

The transmittance of CdSe:Eu films in the VIS-region at different deposition conditions indicates that CdSe:Eu will prove very useful in the manufacture of glasses, vehicle windscreens, optical lenses, windows and optoelectronic devices. The results obtained in this research share similarity with those by [10] for spray-deposited CdSe films. Also, the results displayed high transparency for CdSe:Eu in the VIS-region which agrees with the report of [11]. However, the transparency of CdSe:Eu deposited in this work appear to be higher compared to those obtained by [10-11]. This observation may arise from the addition of rare-earth impurity (europium) to the pure CdSe in this research.

$C:\Users\Dr. E.J. Jeroh\Desktop\PhD Results\Reflectance CdEuSe.jpg$

Figure 3: Reflectance spectra of CdSe:Eu

From figure 3, all the reflection spectra exhibited a descending trend in the VIS-region as wavelength increases. For the films deposited at 10% and 15% dopant concentration, reflection values all through the UV-region were from 6.33% to 19.12% and 1.76% to 19.32% respectively. For the films deposited at 10%, the reflection values were within 2.96% and 5.18% in the VIS-region while for the films deposited at 15% dopant concentrations, reflection value was constant at 1.33% in the VIS-region. For the films deposited at 20% dopant concentration, reflection values recorded in the UV-region and visible region were within 10.61% to 19.69% and 4.48% to 8.91% respectively. Films deposited at 25% and 30% dopant concentrations have reflection values from 5.84% to 19.92% and 4.4% to 19.81% throughout the UV-VIS regions. It is pertinent to observe that in all cases of variations, all the deposited films of CdSe:Eu exhibited poor reflection of light throughout the entire UV-VIS regions. This characteristic of poor reflection exhibited by CdSe:Eu makes it a choice material as anti-reflective coating in solar cells.

The band gaps for CdSe:Eu were obtained by extrapolation of the straight portions of the curves in figures 4a – 4c.

$C:\Users\Dr. E.J. Jeroh\Desktop\PhD Results\CdEuSe 10%.jpg$

Figure 4a: Plot of (αhv)2 versus photon

energy for CdSe:Eu at 10% volume concentration

$C:\Users\Dr. E.J. Jeroh\Desktop\PhD Results\Band Gap CdEuSe 15%.jpg$

Figure 4b: Plot of (αhv)2 versus photon energy for CdSe:Eu at 15%

volume concentration

$C:\Users\Dr. E.J. Jeroh\Desktop\PhD Results\band gap % new.jpg$

Figure 4c: Plot of (αhv)2 versus photon energy for CdSe:Eu at 20%, 25% and 30% volume concentrations

Band gap varies between 3.35 eV and 3.80 eV at varying concentrations. A discending trend in band gap from 3.8 eV to 3.35 eV as volume concentration increases from 10% to 25% volume concentration is observed. However, at 30%, a band gap value of 3.4 eV is attained. Such trend could have resulted due to perceived existence of defect states within the crystal lattice. Band gap values from this research exhibited very strong blue-shift from that of bulk CdSe. This could be ascribed to quantum confinement existence resulting from the nanosized grains reported.

$C:\Users\Dr. E.J. Jeroh\Desktop\PhD Results\SEM RESULTS\C11_02.tif$

Figure 5a: SEM image of CdSe:Eu at

10%

$C:\Users\Dr. E.J. Jeroh\Desktop\PhD Results\SEM RESULTS\C12_02.tif$

Figure 5b: SEM image of CdSe:Eu at

15%

From figures 5a and 5b, the films appear to have a smooth surface morphology. A very close look at the SEM images reveals very small spherical shapes (though, not uniformly spread) which indicate the growth of small crystallites on the film’s surface.

Figures 6a and 6b display the XRD image of CdSe:Eu obtained at a substrate temperature of 360 oC, 10% and 20% dopant concentrations respectively.

$C:\Users\JEROH\Desktop\Ph.D\Graphs\C11 XRD EXT.jpg$

Figure 6a: XRD image of CdSe:Eu at 360oC and 10% dopant concentration

$C:\Users\Dr. E.J. Jeroh\Desktop\PhD Results\XRD CDSEEU 15.jpg 2.jpg$

Figure 6b: XRD image of CdSe:Eu at 360oC and 20% dopant concentration

From figure 6a, the observed diffraction peaks obtained at 2θ values of 28.93o, 30.62o, 34.98o and 51.05o are indexed to the diffraction planes; (100), (101), (102) and (103) which is very close to reported standard values in the JCPDS-15-0105 card number.

From the XRD pattern, the films presents crystalline characteristics and the indexed planes (miller indices or hkl values) suggests a hexagonal (wurtzite) structure for the synthesized CdSe:Eu. The crystallite size corresponding to 2θ values of 28.93o, 30.62o, 34.98o and 51.05o are 38.95 nm, 25.30 nm, 24.16 nm and 21.89 nm respectively.

From figure 6b, no peaks were observed.

$C:\Users\JEROH\Desktop\Ph.D\Graphs\EDX C11 10% (REAL).jpg$

Figure 7: EDX spectra of CdSe:Eu obtained at 360 oC, 10% dopant concentration

Peaks corresponding to cadmium (Cd), selenium (Se) and europium (Eu) are obvious from the EDX spectra figure 7 which indicate the growth of CdSe:Eu film. The peaks assigned to Si, Na, and K are results from the substrate (glass slides) used for the deposition process. The chlorine (Cl) peak results from the HCl used in the deposition process while the oxygen (O) peak is possibly due to atmospheric exposure.

Conclusion

Results and discussions based on synthesizing CdSe:Eu electrostatically have been presented. Absorption peaks evident in the VIS-region suggests evidence of defect states within the crystal. Increase in band gap results from quantum confinement effects. Microstructural analysis shows formation of small nanosized grains, while XRD reveal the crystalline nature of CdSe:Eu. The properties exhibited by the grown films suggest their suitability in the fabrication of anti-reflective coating for solar-cell applications, optical windows and lenses.

References

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[3] S. Singh, A.K. Shrivastava and S. Tapdiya (2017). Synthesis and characterization of Mn composition effect on CdSe thin films. Advanced Materials Proceedings, 2(6), 367-370.

[4] S. Singh and A.K. Shrivastava (2017). Growth and Characterization of Rare Earth Doped Mixed Chalcogenide thin films. Journal of Pure Applied and Industrial Physics, 7(5), 166-170.

[5] O.I. Olusola, O.K. Echendu and I. Dharmadasa (2015). Development of CdSe thin films for application in electronic devices. Journal of Materials Science: Materials in Electronics, 26(2), 1066-1076.

[6] M.A. Zubair, M.T. Chowdhury, M.S. Bashar, M.A. Sami and M.F. Islam. (2019). Thickness dependent correlation between structural and optical properties of textured CdSe thin film. Journal of Applied Physics, 9, 045123.

[7] O.E. Raola and G.F. Strouse (2002). Synthesis and characterization of Eu-doped cadmium selenide nanocrystals. Nano Letters 2(12), 1443-1447.

[8] M.D. Jeroh, A.J. Ekpunobi and D.N. Okoli (2018). Optical analytical studies of electrostatic-sprayed Eu-doped cadmium selenide nanofilms at different temperatures. Journal of Nano- and Electronic Physics, 10(3), 03006-1 – 03006-5.

[9] Y. Hanifehpour and S.W. Joo (2018). Synthesis, characterization and sonophotocatalytic degradation of an azo dye on europium doped cadmium selenide nanoparticles. Nanochemical Research, 3(2), 178-188.

[10] R.M. Meshram and R.M. Thombre (2015). Structural and optical properties of CdSe thin

films prepared by spray pyrolysis technique. International Journal of Advances in

Science Engineering and Technology, Special Issue (1), 167-170.

[11] S. Thirumavalavan, K. Mani, and S. Suresh (2015). Structural, surface morphology, optical and electrical investigation of CdSe thin films. Chalcogenide Letters, 12(5), 237- 246.

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Optical and structural characterization of CdSe:Eu films at different volumes of europium concentration.

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