KCN Chemical Etch for Interface Engineering in Cu<sub>2</sub>ZnSnSe<sub>4</sub> Solar Cells

Buffière, Marie; Brammertz, Guy; Sahayaraj, Sylvester; Batuk, Maria; Khelifi, Samira; Mangin, Denis; Mel, Abdel Aziz El; Arzel, Ludovic; Hadermann, Joke; Meuris, Marc; Poortmans, Jef

doi:10.1021/acsami.5b02122

Cited by 66 publications

(51 citation statements)

References 38 publications

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“…Furthermore, our procedure does not contain any wet chemical etching step, which is generally used for removing secondary phases and/or improving the absorber surface. [13][14][15] These results demonstrate that as-grown kesterite absorbers can still perform at high-efficiency levels without additional process steps.…”

Section: Methodsmentioning

confidence: 74%

“…It is essential to underline that we apply only a facile one‐stage annealing approach, which does not require any complex temperature profile or any low‐temperature post‐annealing step. Furthermore, our procedure does not contain any wet chemical etching step, which is generally used for removing secondary phases and/or improving the absorber surface . These results demonstrate that as‐grown kesterite absorbers can still perform at high‐efficiency levels without additional process steps.…”

Section: Resultsmentioning

confidence: 86%

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Resilient and reproducible processing for CZTSe solar cells in the range of 10%

Taskesen

Steininger

Chen

et al. 2018

Progress in Photovoltaics

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In this paper, we present our route to fabricate Cu2ZnSnSe4 (CZTSe) thin films, which allows to achieve reproducible processing of kesterite absorber, that leads to efficiencies in the range of 10%. The article mainly focuses on the annealing process and demonstrates that controlling of the reactor pressure for selenization can be reliably used to tune the losses of volatile constituents in the absorber, enabling adjustments on the properties of the film and solar cell. The findings reveal a noteworthy resilience to small changes of the process parameters in the vicinity of optimum conditions. Interestingly, a certain pressure range for optimum Zn and Sn composition exists, which results in a broad and stable process window and enables reproducible processing of CZTSe with high power conversion efficiencies. The established process also allows simple upscaling of the device area and results in a power conversion efficiency of ≈ 8% on a large area of 2.85 cm2. The highest efficiencies achieved by our process are around 11% for smaller lab scale devices.

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Section: Methodsmentioning

confidence: 74%

Section: Resultsmentioning

confidence: 86%

Resilient and reproducible processing for CZTSe solar cells in the range of 10%

Taskesen

Steininger

Chen

et al. 2018

Progress in Photovoltaics

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“…Although lower temperatures might be needed in the case of a thin film compound, other techniques might need to be envisaged to lower the temperature (and duration) of the post‐annealing treatment, such as the use of additives (i.e., halide compounds); solution based sulfurization techniques such as using 3‐mercaptopropionic acid as sulfur source and solvent could also be envisaged; 2) The review of the synthesis methods of the chalcogenide ABX 3 compounds have also shown that, as for most ternary compound, a slight deviation from the stoichiometric compound and/or an inadequate processing temperature will lead to the formation of secondary phases; depending on their location and their nature (i.e., conductivity, bandgap, etc. ), such secondary phases can have either a benign or a detrimental effect on the performance of thin film solar cells; a selective etching process done after the absorber processing can be envisaged to remove the secondary phases, as in the case of CuSe secondary phase in CIGS absorber that are etched by KCN treatment or alternatives . Further calculations might also be needed to determine the tolerance of the ABX 3 structure to sub‐stochiometric composition; 3) It is likely that the structure of the ABX 3 solar cell will differ from the standard structures of MAPI perovskite PV devices, due to the requirement of the processing conditions of the ABX 3 thin film; for example, the TiO 2 thin film usually used as ETL in the n‐i‐p structure would be converted into TiS 2 (or TiSe 2 ) during the sulfurization (selenization) step if used underneath the precursor thin film; Furthermore, the band alignment at the interface surrounding the absorber will also need to be adapted to the band structure of the absorber; therefore, the full solar cell structure will need to be redefined, depending on the absorber properties, based either on the n–i–p or the p–n structure concepts.…”

Section: Discussionmentioning

confidence: 99%

Chalcogenide Materials and Derivatives for Photovoltaic Applications

2019

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Chalcogenide AB(S,Se)3 materials have recently attracted increased attention as they could simultaneously solve both the stability and toxicity issues faced by conventional perovskite solar cells. Computer‐aided design of metal chalcogenide semiconductors has experienced important progress over the past few years, leading to the discovery of very promising AB(S,Se)3 compounds and derivatives for application as absorbers in thin‐film photovoltaic devices. Experimental evidence demonstrates that the synthesis of such compounds is possible, confirming the theoretical predictions, although more research work needs to be done to further investigate the optoelectrical properties of the corresponding thin films. With the aim to provide an exhaustive starting point to further develop chalcogenide absorbers and related devices, this Review presents both an overview of the predicted chalcogenide materials and interesting derivatives for thin‐film solar cells applications, as well as a summary of the synthesis techniques developed so far to prepare such materials. The possible challenges that can be encountered during the development of chalcogenide‐based solar cells are also discussed.

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“…However, the interface defects are inevitable and play an essential role in device operation in practice. [157][158][159] As a terminal of periodical microcrystals which constitute the absorber layer, the surface usually has different chemical composition from the bulk, which consequently constructs a different defects structure on the surface of the absorber layer. For example, a Cu-depleted surface is commonly observed in generally adopted Cu-poor CIGS films.…”

Section: Engineering the Interface Defects And Band Bendingmentioning

confidence: 99%

Cation Substitution in Earth‐Abundant Kesterite Photovoltaic Materials

et al. 2018

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As a promising candidate for low‐cost and environmentally friendly thin‐film photovoltaics, the emerging kesterite‐based Cu2ZnSn(S,Se)4 (CZTSSe) solar cells have experienced rapid advances over the past decade. However, the record efficiency of CZTSSe solar cells (12.6%) is still significantly lower than those of its predecessors Cu(In,Ga)Se2 (CIGS) and CdTe thin‐film solar cells. This record has remained for several years. The main obstacle for this stagnation is unanimously attributed to the large open‐circuit voltage (V OC) deficit. In addition to cation disordering and the associated band tailing, unpassivated interface defects and undesirable energy band alignment are two other culprits that account for the large V OC deficit in kesterite solar cells. To capture the great potential of kesterite solar cells as prospective earth‐abundant photovoltaic technology, current research focuses on cation substitution for CZTSSe‐based materials. The aim here is to examine recent efforts to overcome the V OC limit of kesterite solar cells by cation substitution and to further illuminate several emerging prospective strategies, including: i) suppressing the cation disordering by distant isoelectronic cation substitution, ii) optimizing the junction band alignment and constructing a graded bandgap in absorber, and iii) engineering the interface defects and enhancing the junction band bending.

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KCN Chemical Etch for Interface Engineering in Cu₂ZnSnSe₄ Solar Cells

Cited by 66 publications

References 38 publications

Resilient and reproducible processing for CZTSe solar cells in the range of 10%

Resilient and reproducible processing for CZTSe solar cells in the range of 10%

Chalcogenide Materials and Derivatives for Photovoltaic Applications

Cation Substitution in Earth‐Abundant Kesterite Photovoltaic Materials

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KCN Chemical Etch for Interface Engineering in Cu2ZnSnSe4 Solar Cells

Cited by 66 publications

References 38 publications

Resilient and reproducible processing for CZTSe solar cells in the range of 10%

Resilient and reproducible processing for CZTSe solar cells in the range of 10%

Chalcogenide Materials and Derivatives for Photovoltaic Applications

Cation Substitution in Earth‐Abundant Kesterite Photovoltaic Materials

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KCN Chemical Etch for Interface Engineering in Cu₂ZnSnSe₄ Solar Cells