Raman spectra of Cu2BIICIVX4VI magnetic quaternary semiconductor compounds with tetragonal stannite type structure

Rincón, C.; Quintero, M.; Power, Ch.; Moreno, E.; Quintero, E.; Henao, J. A.; Macías, Mario A.; Morocoima, M.

doi:10.1063/1.4921438

Cited by 21 publications

(14 citation statements)

References 35 publications

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“…Because for α‐Cu 2 ZnGeTe 4 the three A ‐symmetry modes expected involve only the motion of the Te anion at 8 g position (see Table ), their vibrational frequencies can be estimated from the model by the ST quaternaries mentioned above by assuming that the frequency of these three modes in increasing energy depend only of Zn–Te, Cu–Te, and Ge–Te bond stretching force constants, respectively. This yields for the frequencies of these A ‐symmetry KS modes the values 122, 124, and 141 (± 5) cm −1 in good agreement with the three strongest peaks observed in the present Raman spectrum at 116, 119, and 139 cm −1 . The remaining Raman lines at 81, 89, 97, and 263 cm −1 can be tentatively ascribed to B or E ‐symmetry kesterite modes.…”

Section: Resultssupporting

confidence: 88%

“…For Cu 2 GeTe 3 , to the best of our knowledge, no Raman studies have been reported. However, since for the

C {normalu}_{2} {normalB}^{I V} {normalX}_{3}^{V I}

ternary compounds main Raman peaks observed are related to vibrations of the X VI anion , it is expected that Raman spectrum for Cu 2 SnTe 3 should be similar to that of Cu 2 GeTe 3 . Thus, lines at 123 and 142 cm −1 of the present spectrum which coincides with those of the main lines reported for Cu 2 SnTe 3 are tentatively assigned to Cu 2 GeTe 3 .…”

Section: Resultsmentioning

confidence: 99%

“…Thus, lines at 123 and 142 cm −1 of the present spectrum which coincides with those of the main lines reported for Cu 2 SnTe 3 are tentatively assigned to Cu 2 GeTe 3 . On the other hand, the frequency of the three A ‐symmetry modes expected for α‐Cu 2 ZnGeTe 4 could be estimated from a model developed for

C {normalu}_{2} {normalB}^{I I} {normalC}^{I V} {normalX}_{4}^{V I}

ST‐type compounds which is based on the assumption that the two Raman A 1 ‐symmetry modes detected in these materials originate from the motion of the X VI anions around the Cu or C IV cations remaining at rest . Because for α‐Cu 2 ZnGeTe 4 the three A ‐symmetry modes expected involve only the motion of the Te anion at 8 g position (see Table ), their vibrational frequencies can be estimated from the model by the ST quaternaries mentioned above by assuming that the frequency of these three modes in increasing energy depend only of Zn–Te, Cu–Te, and Ge–Te bond stretching force constants, respectively.…”

Section: Resultsmentioning

confidence: 99%

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Structural characterization of the high‐temperature modification of the Cu₂ZnGeTe₄ quaternary semiconductor compound

Nieves

Delgado

Marcano

et al. 2016

Physica Status Solidi (b)

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A combined study of the X-ray powder diffraction, differential thermal analysis, optical absorption, and Raman spectroscopy of the high-temperature modification of Cu 2 ZnGeTe 4 quaternary semiconductor, obtained by fast quenching from 820 K to ice water temperature, has been done. It has been found that this phase crystallizes in a tetragonal kesterite-type structure. From the analysis of the absorption coefficient spectra, the band gap energy of this material at room temperature has been found to be 1.49 eV. An optical transition from defect acceptor states to the conduction band is also observed below the fundamental absorption edge. Three strongest Raman lines observed at 116, 119, and 139 cm À1 have been assigned to the A-symmetry modes. Also, lines at 81, 89, 97, and 263 cm À1 tentatively ascribed as B or E-symmetry modes have been detected from the spectrum. The presence in this hightemperature modification of ZnTe and Cu 2 GeTe 3 secondary phases has been detected by both XRD and Raman spectroscopy.

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Section: Resultssupporting

confidence: 88%

“…For Cu 2 GeTe 3 , to the best of our knowledge, no Raman studies have been reported. However, since for the

C {normalu}_{2} {normalB}^{I V} {normalX}_{3}^{V I}

Section: Resultsmentioning

confidence: 99%

C {normalu}_{2} {normalB}^{I I} {normalC}^{I V} {normalX}_{4}^{V I}

Section: Resultsmentioning

confidence: 99%

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Structural characterization of the high‐temperature modification of the Cu₂ZnGeTe₄ quaternary semiconductor compound

Nieves

Delgado

Marcano

et al. 2016

Physica Status Solidi (b)

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“…Raman spectra of the pure‐CZTSSe absorber and CMZTSSe thin film excited at 514 nm are shown in Figure S3, Supporting Information. It is observed that three most intense Raman peaks are centered at around 166, 189, and 228 cm −1 , respectively, which are indexed as the Raman characteristic peaks of CZTSe or CMTSe . Obviously, the main peaks shift to lower wavenumber as Zn is substituted partially by Mn, which is because the three intense Raman peaks of CMTSe are located in the lower wavenumber than those of CZTSe.…”

Section: Resultsmentioning

confidence: 98%

Efficient Optimization of the Performance of Mn²⁺‐Doped Kesterite Solar Cell: Machine Learning Aided Synthesis of High Efficient Cu₂(Mn,Zn)Sn(S,Se)₄ Solar Cells

Hou

Gao

et al. 2018

Solar RRL

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Isoelectronic cation substitution is a potential method to decrease the density of Cu‐Zn anti‐site defects in CZTSSe, thus improving the VOC and performance of CZTSSe solar cells. The proper doping concentration is determined traditionally by the trial and error approach, costing much time, and materials. How to shorten the time to find the proper doping concentration is a big challenge for the development of solar cells. Here, by utilizing the machine learning model, the authors carry out an adaptive design for predicting the optimal doping ratio of Mn2+ ions in CZTSSe solar cells for improved solar cell efficiency. With the help of machine learning prediction, the authors rapidly and efficiently find the optimal doping ratio of Mn2+ in CZTSSe solar cells to be 0.05, achieving a highest solar cell efficiency of 8.9% in experiment. Further experimental characterizations of Mn‐doped CZTSSe show that the defect in CZTSSe after Mn doping is changed from an anti‐site CuZn defect to VCu defect. Our findings suggest that machine learning is a very powerful and efficient approach to aid the development of solar cell materials for its application in the photovoltaic field.

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“…This will directly influence the energy of the phonons, which will lead to a shift of Raman peaks while maintaining the overall spectrum pattern. Taking this into account, a typical Raman spectrum of any kesterite-type quaternary compound can be predicted [42]. On the other hand, using excitation wavelengths close to the resonant conditions can have a significant effect on the fingerprint of Raman spectra.…”

Section: Fingerprint Raman Spectramentioning

confidence: 99%

Point defects, compositional fluctuations, and secondary phases in non-stoichiometric kesterites

et al. 2019

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The efficiency of kesterite-based solar cells is limited by various non-ideal recombination paths, amongst others by a high density of defect states and by the presence of binary or ternary secondary phases within the absorber layer. Pronounced compositional variations and secondary phase segregation are indeed typical features of non-stoichiometric kesterite materials. Certainly kesterite-based thin film solar cells with an offstoichiometric absorber layer composition, especially Cu-poor/Zn-rich, achieved the highest efficiencies, but deviations from the stoichiometric composition lead to the formation of intrinsic point defects (vacancies, anti-sites, and interstitials) in the kesterite-type material. In addition, a non-stoichiometric composition is usually associated with the formation of an undesirable side phase (secondary phases). Thus the correlation between off-stoichiometry and intrinsic point defects as well as the identification and quantification of secondary phases and compositional fluctuations in non-stoichiometric kesterite materials is of great importance for the understanding and rational design of solar cell devices. This paper summarizes the latest achievements in the investigation of identification and quantification of intrinsic point defects, compositional fluctuations, and secondary phases in non-stoichiometric kesterite-type materials.This work focuses on structural variations in kesterite-type compound semiconductors, in particular Cu/Zn disorder and intrinsic point defects, as well as on compositional variations, in particular stoichiometry deviations in the kesterite-type phase and the segregation of related binary and ternary phases.This review provides the vital approaches by discussing results and trends concerning intrinsic point defects and structural disorder, compositional fluctuations, and secondary phases on a macroscopic and microscopic scale and even on the nano-scale. Various analytical methods have been used in these studies.The review comprises five parts:A. Crystal structure, structural disorder, and intrinsic point defects in kesterites B. Raman spectroscopy investigations on kesterites OPEN ACCESS RECEIVED

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Raman spectra of Cu2BIICIVX4VI magnetic quaternary semiconductor compounds with tetragonal stannite type structure

Cited by 21 publications

References 35 publications

Structural characterization of the high‐temperature modification of the Cu₂ZnGeTe₄ quaternary semiconductor compound

Structural characterization of the high‐temperature modification of the Cu₂ZnGeTe₄ quaternary semiconductor compound

Efficient Optimization of the Performance of Mn²⁺‐Doped Kesterite Solar Cell: Machine Learning Aided Synthesis of High Efficient Cu₂(Mn,Zn)Sn(S,Se)₄ Solar Cells

Point defects, compositional fluctuations, and secondary phases in non-stoichiometric kesterites

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Raman spectra of Cu2BIICIVX4VI magnetic quaternary semiconductor compounds with tetragonal stannite type structure

Cited by 21 publications

References 35 publications

Structural characterization of the high‐temperature modification of the Cu2ZnGeTe4 quaternary semiconductor compound

Structural characterization of the high‐temperature modification of the Cu2ZnGeTe4 quaternary semiconductor compound

Efficient Optimization of the Performance of Mn2+‐Doped Kesterite Solar Cell: Machine Learning Aided Synthesis of High Efficient Cu2(Mn,Zn)Sn(S,Se)4 Solar Cells

Point defects, compositional fluctuations, and secondary phases in non-stoichiometric kesterites

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Structural characterization of the high‐temperature modification of the Cu₂ZnGeTe₄ quaternary semiconductor compound

Structural characterization of the high‐temperature modification of the Cu₂ZnGeTe₄ quaternary semiconductor compound

Efficient Optimization of the Performance of Mn²⁺‐Doped Kesterite Solar Cell: Machine Learning Aided Synthesis of High Efficient Cu₂(Mn,Zn)Sn(S,Se)₄ Solar Cells