Detailed photoluminescence study of vapor deposited  films of different surface morphology

Sträter, Hendrik; Haaf, Sebastian ten; Brüggemann, R.; Jakob, G.; Nilius, Niklas; Bauer, G.H.

doi:10.1002/pssb.201451271

Cited by 6 publications

(9 citation statements)

References 39 publications

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“…The mean temperature is about 40 K above room temperature, what is most likely an effect of the local heating due to the excitation laser and limited heat conduction. Similar heat depositions have been reported before [22,23]. The optical band gap is about 1.50 eV and coincides with the reported band gaps for this material.…”

Section: Resultssupporting

confidence: 88%

“…Due to the non-perfect quantitative calibration the exact value of the QFL-splitting of 1.255 eV might be not precise and is probably overestimated. Nevertheless, as shown in a recent publication, the standard deviation of 24 meV is within an error of 1 meV [23]. The Urbach energy E U evaluated in the sub-gap regime is about 20 meV and is in the range of observed Urbach energies in CuInS 2 [24,25].…”

Section: Resultsmentioning

confidence: 89%

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PARPLE: Detailed automatized and parallel evaluation of luminescence mappings

Sträter

2015

Computer Physics Communications

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Section: Resultssupporting

confidence: 88%

Section: Resultsmentioning

confidence: 89%

PARPLE: Detailed automatized and parallel evaluation of luminescence mappings

Sträter

2015

Computer Physics Communications

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“…For example, a varying band structure of the semiconductor or defect absorption may lead to a larger heat deposition, or the grain boundary can transport the heat differently depending from the illuminated spot to the surrounding material. A similar observation of a lateral temperature distribution has been made by Delamarre et al for a

{CuIn}_{1 - x} {Ga}_{x} {Se}_{2}

thin film and inhomogeneous temperatures along the film have also been observed for the binary semiconductors Cu 2 S and Bi 2 S 3 .…”

Section: Mathematical Frameworksupporting

confidence: 83%

“…The reason for the lateral temperature distribution most probably results from different chemical compositions, opto-electronical properties, and heat conductivities of the grains forming the film. For example, a varying band structure of the semiconductor or defect absorption may lead to a larger heat deposition, or the grain boundary can [18]. We now consider a set of N different PL spectra recorded under the same experimental conditions.…”

Section: Variation Of the Qfl-splittingmentioning

confidence: 99%

Avoiding arbitrarily wrong microluminescence statistics due to a non-quantitatively calibrated setup

Sträter

Nilius

Brüggemann

2017

Phys. Status Solidi B

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Photoluminescence (PL) measurements on the normalμm scale are a powerful tool to examine thin film semiconductors with respect to lateral inhomogeneities of their opto‐electronic properties. For practical reasons, the determination of the standard deviation of the laterally resolved splitting of quasi‐Fermi levels (QFL) is often performed with an experimental setup that only has been calibrated spectrally but not with respect to the quantitatively emitted photon flux. We show that the omission of the absolute PL photon flux can lead to arbitrarily wrong distributions of the QFL‐splitting and correlations between the QFL‐splitting and other opto‐electronic properties. For a better understanding, we present a algebraical formalism of the dependence on the absolute calibration and demonstrate the effect of a wrong calibration using two different thin film absorbers. Finally, a method to estimate the true statistics with sufficient accuracy is presented.

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“…For thin-film investigation with a calibrated PL, the spectral variation of Θ is often disregarded by simply setting Θ ¼ 1 in Eq. (13) [26,[29][30][31]. Here, we compare two approximations for Θ from the perspectives of QFLS and absorption coefficient measurement.…”

Section: B Influence Of the Optical Factormentioning

confidence: 99%

Absorption Coefficient of a Semiconductor Thin Film from Photoluminescence

et al. 2018

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The photoluminescence (PL) of semiconductors can be used to determine their absorption coefficient (α) using Planck's generalized law. The standard method, suitable only for self-supported thick samples, like wafers, is extended to multilayer thin films by means of the transfer-matrix method to include the effect of the substrate and optional front layers. α values measured on various thin-film solar-cell absorbers by both PL and photothermal deflection spectroscopy (PDS) show good agreement. PL measurements are extremely sensitive to the semiconductor absorption and allow us to advantageously circumvent parasitic absorption from the substrate; thus, α can be accurately determined down to very low values, allowing us to investigate deep band tails with a higher dynamic range than in any other method, including spectrophotometry and PDS.

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Detailed photoluminescence study of vapor deposited films of different surface morphology

Cited by 6 publications

References 39 publications

PARPLE: Detailed automatized and parallel evaluation of luminescence mappings

PARPLE: Detailed automatized and parallel evaluation of luminescence mappings

Avoiding arbitrarily wrong microluminescence statistics due to a non-quantitatively calibrated setup

Absorption Coefficient of a Semiconductor Thin Film from Photoluminescence

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