Photoluminescence study of polycrystalline photovoltaic CdS thin film layers grown by close-spaced sublimation and chemical bath deposition

Abken, Anke E.; Halliday, D.P.; Durose, K.

doi:10.1063/1.3074504

Cited by 124 publications

(64 citation statements)

References 45 publications

(75 reference statements)

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“…The broad defect-related band located around 1.5-2.0 eV is ascribed to the emission between the energy levels of the defects, such as, Cd vacancy (V Cd ), surface states, Cl at the lattice of S (Cl S ), S vacancy (V S ), interstitial Cd (Cdi) and the the valence band state (VB), impurities and acceptor. [24][25][26] The detailed peak components, which are ascribed to the specific emissions, are shown in Fig. 4(b).…”

Section: Resultsmentioning

confidence: 99%

Cu-doped CdS and its application in CdTe thin film solar cell

Deng

Yang

et al. 2016

AIP Advances

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Cu is widely used in the back contact formation of CdTe thin film solar cells. However, Cu is easily to diffuse from the back contact into the CdTe absorber layer and even to the cell junction interface CdS/CdTe. This phenomenon is generally believed to be the main factor affecting the CdTe solar cell stability. In this study Cu was intentionally doped in CdS thin film to study its effect on the microstructural, optical and electrical properties of the CdS material. Upon Cu doping, the VCd− and the surface-state-related photoluminescence emissions were dramatically decreased/quenched. The presence of Cu atom hindered the recrystallization/coalescence of the nano-sized grains in the as-deposited CdS film during the air and the CdCl2 annealing. CdTe thin film solar cell fabricated with Cu-doped CdS window layers demonstrated much decreased fill factor, which was induced by the increased space-charge recombination near the p-n junction and the worsened junction crystalline quality. Temperature dependent current-voltage curve measurement indicated that the doped Cu in the CdS window layer was not stable at both room and higher temperatures.

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Section: Resultsmentioning

confidence: 99%

Cu-doped CdS and its application in CdTe thin film solar cell

Deng

Yang

et al. 2016

AIP Advances

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“…For four studied CBD-CdS samples, another broad band, band d, is observed around 1.88 eV, this band named the "orange band" has been observed between 2.03-2.08 eV [40,41], it is possibly associated to a donoracceptor pair (DAP) radiative transition between a donor level related to interstitial cadmium (I 2+ Cd ) and an unidentified acceptor level. The ionization energy of this donor has estimated to be between 0.12 and 0.26 eV, which corresponds to (I 2+ Cd ) [38].…”

Section: +mentioning

confidence: 99%

Rare earths (Ce, Eu) molar concentration-dependent of the structural and optical properties of CBD-CdS nanofilms

et al. 2018

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It presents the characterization of rare earths (Eu,Ce)-doped CdS nanofilms that were synthesised by the growth technique chemical bath deposition (CBD) at the reservoir temperature of 70 ± 2• C. The doping of CdS with rare earths is performed by varying the synthesis time from 60 to 135 min. The rare earths molar concentration was range from 0.0 ≤ x ≤ 3.5, which was determined by energy dispersive X-ray spectroscopy. X-ray diffraction (XRD) analysis and Raman scattering reveal that CdS nanofilms showed the zinc blende (ZB) crystalline phase. The CdS average nanocrystal size was ranged from 1.84 to 2.67 nm that was determined by the Debye-Scherrer equation from ZB (111) direction, which was confirmed by transmission electron microscopy. Raman scattering shows that the lattice dynamics is characteristic of bimodal behaviour and the multipeaks adjust of the first optical longitudinal mode for the (Eu,Ce)-doped CdS, which denotes the Raman shift of the characteristic peak about 305 cm −1 of the CdS nanocrystals. The CdS nanofilms exhibit a direct bandgap that slightly decreases with increasing doping, from 2.50 to 2.42 eV, which was obtained by room temperature transmittance. The room-temperature photoluminescence of CdS shows the band-to-band transition at 2.88 eV, which is associated to quantum confinement and a dominant radiative band at 2.37 eV that is called the optical signature of interstitial oxygen. The Eu 3+ -doped CdS photoluminescence shows the dominant radiative band at 2.15 eV, which is associated to the intra-4f radiative transition of Eu 3+ ions that corresponds to the magnetic dipole transition, ( 5 D0→ 7 F 1 ).For the Ce 3+ -doped CdS the dominant radiative transition, at 2.06 eV, is clearly redshifted, although the passivation of the CdS nanofilms byCe was approximately by a factor about 21 for the best results.Keywords: CdS; Chemical bath deposition; Rare earths; cerium; europium.Se presenta la caracterización de las nanopelículas de CdS impurificadas con tierras raras (Eu,Ce) que se sintetizaron mediante la técnica de crecimiento deposición de baño químico (CBD) a la temperatura del reservorio de 70 ± 2 • C. La impurificación de CdS con tierras raras se realizó variando el tiempo de síntesis de 60 a 135 min. La concentración molar de las tierras raras fue de 0.0 ≤ x ≤ 3.5, que se determinó mediante espectroscopia de rayos X de energía dispersiva. El análisis de difracción de rayos X (XRD) y dispersión de Raman revelan que las nanopelículas de CdS mostraron la fase cristalina de zinc blenda (ZB). El tamaño medio de los nanocristales de CdS varió de 1.84 a 2.67 nm, que se determinó mediante la ecuación de Debye-Scherrer a partir de la dirección ZB (111), que se confirmó mediante microscopía electrónica de transmisión. La dispersión Raman muestra que la dinámica de la red es característica del comportamiento bimodal y el ajuste multipicos del primer modo longitudinalóptico para el CdS impurificado con (Eu, Ce), el cual denota el desplazamiento Raman del pico característico en aproximadamente 305 ...

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“…Accordingly a lot of preparing techniques, such as spray pyrolysis [8], close-spaced sublimation [9], chemical vapor deposition [10] and chemical bath deposition (CBD) [9] etc., have been developed for growing high-quality CdS thin films on different substrates. Among the methods, CBD deposition is thought to be most suitable for preparing CdS thin films with large-area uniformity, strong film-substrate adhesion and high reproducibility.…”

Section: Introductionmentioning

confidence: 99%

Temperature-dependent photoluminescence and mechanism of CdS thin film grown on Si nanoporous pillar array

Yan

et al. 2015

Applied Surface Science

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Photoluminescence study of polycrystalline photovoltaic CdS thin film layers grown by close-spaced sublimation and chemical bath deposition

Cited by 124 publications

References 45 publications

Cu-doped CdS and its application in CdTe thin film solar cell

Cu-doped CdS and its application in CdTe thin film solar cell

Rare earths (Ce, Eu) molar concentration-dependent of the structural and optical properties of CBD-CdS nanofilms

Temperature-dependent photoluminescence and mechanism of CdS thin film grown on Si nanoporous pillar array

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