Features of KF and NaF Postdeposition Treatments of Cu(In,Ga)Se<sub>2</sub> Absorbers for High Efficiency Thin Film Solar Cells

Reinhard, Patrick; Bissig, Benjamin; Pianezzi, Fabian; Avancini, Enrico; Hagendorfer, Harald; Keller, Debora; Fuchs, Peter; Döbeli, M.; Vigo, Carlos; Crivelli, P.; Nishiwaki, Shiro; Buecheler, Stephan; Tiwari, Ayodhya N.

doi:10.1021/acs.chemmater.5b02335

Cited by 179 publications

(221 citation statements)

References 43 publications

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“…For the NaF/KF-PDT CIGSe samples, we detect no Na signal, which may be due to the suggested "ion-exchange mechanism" explaining that K replaces Na in the CIGSe during the PDT. [7], [18] Comparing the two NaF/KF-PDT CIGSe absorbers, it is apparent that for the alkali-poor NaF/KF-PDT CIGSe the intensity of the K-related photoemission signals (K 2s and K 2p) is significantly lower than the respective peak intensities for the alkali-rich NaF/KF-PDT CIGSe (see also Fig. 3c2)).…”

Section: Methodsmentioning

confidence: 94%

NaF/KF post-deposition treatments and their influence on the structure of Cu(In, Ga)Se<inf>2</inf> absorber surfaces

Handick

Reinhard

Wilks

et al. 2016

2016 IEEE 43rd Photovoltaic Specialists Conference (PVSC)

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-To determine the influence of NaF/KF-postdeposition treatments (PDT) on the chemical and topographical surface structure of Cu(In,Ga)Se2 (CIGSe) solar cell absorbers, we have used synchrotron-based hard x-ray photoelectron spectroscopy (HAXPES) and scanning electron microscopy (SEM). Variations of the PDT parameters can be used to tune thickness and degree of surface nanopatterning; here we find that the nanopatterning is more pronounced on CIGSe surfaces having more potassium and less copper and gallium. Detailed analysis of Se 3d and In 4d photoemission spectra reveals the presence of (at least) two different species, which indicate the formation of a (nanopatterned) K-In-Se-type surface layer.Index Terms -alkali post-deposition treatment, chalcopyrite thin-film solar cells, chemical structure, hard x-ray photoelectron spectroscopy.

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Section: Methodsmentioning

confidence: 94%

NaF/KF post-deposition treatments and their influence on the structure of Cu(In, Ga)Se<inf>2</inf> absorber surfaces

Handick

Reinhard

Wilks

et al. 2016

2016 IEEE 43rd Photovoltaic Specialists Conference (PVSC)

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“…Semiconductor surfaces, especially semiconductor-metal interfaces, can host several interface defects, leading to high surface recombination velocities, which in turn lower the electrical performance of solar cells. [36,37] These findings have motivated device simulations that have predicted gains up to 3% (in absolute power conversion efficiency) in fully passivated solar cells. The field effect passivation occurs by the presence of a built-in electric field that arises from the high density of fixed charge from the commonly used dielectric materials of the passivation layer.…”

Section: Introductionmentioning

confidence: 91%

Passivation of Interfaces in Thin Film Solar Cells: Understanding the Effects of a Nanostructured Rear Point Contact Layer

Salomé

Vermang

Ribeiro‐Andrade

et al. 2017

Adv Materials Inter

110

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Thin film solar cells based in Cu(In,Ga)Se2 (CIGS) are among the most efficient polycrystalline solar cells, surpassing CdTe and even polycrystalline silicon solar cells. For further developments, the CIGS technology has to start incorporating different solar cell architectures and strategies that allow for very low interface recombination. In this work, ultrathin 350 nm CIGS solar cells with a rear interface passivation strategy are studied and characterized. The rear passivation is achieved using an Al2O3 nanopatterned point structure. Using the cell results, photoluminescence measurements, and detailed optical simulations based on the experimental results, it is shown that by including the nanopatterned point contact structure, the interface defect concentration lowers, which ultimately leads to an increase of solar cell electrical performance mostly by increase of the open circuit voltage. Gains to the short circuit current are distributed between an increased rear optical reflection and also due to electrical effects. The approach of mixing several techniques allows us to make a discussion considering the different passivation gains, which has not been done in detail in previous works. A solar cell with a nanopatterned rear contact and a 350 nm thick CIGS absorber provides an average power conversion efficiency close to 10%.

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“…Werner et al investigated a large set of samples with various PDTs and showed that the main capacitance step has the same origin independent of the alkaline PDT and is consistent with the capacitance step labeled "N1." [27] To extract the drop in capacitance and the activation energy of the capacitance step, the fitting method proposed by Weiss et al is applied to the capacitance spectra. [28] The activation energies of the main capacitance step show a good correlation to the incorporated Rb amount as depicted in Figure 7a.…”

Section: Injection Barrier Formationmentioning

confidence: 99%

Injection Current Barrier Formation for RbF Postdeposition‐Treated Cu(In,Ga)Se₂‐Based Solar Cells

Weiss

Nishiwaki

Bissig

et al. 2017

Adv Materials Inter

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Among the thin‐film solar cell technologies, Cu(In,Ga)Se2‐based solar cells demonstrate the highest efficiencies, where the recent boost in efficiency is triggered by a KF postdeposition treatment (PDT). In this contribution, Cu(In,Ga)Se2‐based solar cells are fabricated using RbF PDTs after absorber layer growth with varying substrate and RbF source temperature. The electronic charge transport properties of the solar cell devices are investigated using temperature‐dependent current–voltage analysis and admittance spectroscopy. To investigate the observed transport barriers, a novel concept based on the differential series resistance is proposed. This approach is supported by simulations of current–voltage curves, which reproduce qualitatively experimental data. Experimentally, two parallel conduction paths are found, which act as barriers with different activation energies and impede the charge carrier transport. Both the thickness and height of these barriers increase with an increasing amount of incorporated Rb and can lead to losses in the fill factor and power conversion efficiency at room temperature. Etching in HCl prior to CdS buffer layer deposition reduces the barrier width and can recover these losses.

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Features of KF and NaF Postdeposition Treatments of Cu(In,Ga)Se₂ Absorbers for High Efficiency Thin Film Solar Cells

Cited by 179 publications

References 43 publications

NaF/KF post-deposition treatments and their influence on the structure of Cu(In, Ga)Se<inf>2</inf> absorber surfaces

NaF/KF post-deposition treatments and their influence on the structure of Cu(In, Ga)Se<inf>2</inf> absorber surfaces

Passivation of Interfaces in Thin Film Solar Cells: Understanding the Effects of a Nanostructured Rear Point Contact Layer

Injection Current Barrier Formation for RbF Postdeposition‐Treated Cu(In,Ga)Se₂‐Based Solar Cells

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Features of KF and NaF Postdeposition Treatments of Cu(In,Ga)Se2 Absorbers for High Efficiency Thin Film Solar Cells

Cited by 179 publications

References 43 publications

NaF/KF post-deposition treatments and their influence on the structure of Cu(In, Ga)Se<inf>2</inf> absorber surfaces

NaF/KF post-deposition treatments and their influence on the structure of Cu(In, Ga)Se<inf>2</inf> absorber surfaces

Passivation of Interfaces in Thin Film Solar Cells: Understanding the Effects of a Nanostructured Rear Point Contact Layer

Injection Current Barrier Formation for RbF Postdeposition‐Treated Cu(In,Ga)Se2‐Based Solar Cells

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Product

Resources

About

Features of KF and NaF Postdeposition Treatments of Cu(In,Ga)Se₂ Absorbers for High Efficiency Thin Film Solar Cells

Injection Current Barrier Formation for RbF Postdeposition‐Treated Cu(In,Ga)Se₂‐Based Solar Cells