Reaction Pathway for Efficient Cu<sub>2</sub>ZnSnSe<sub>4</sub> Solar Cells from Alloyed CuSn Precursor via a Cu‐Rich Selenization Stage

Pareek, Devendra; Taskesen, Teoman; Marquez, J.A.; Stange, Helena; Levcenco, Sergiu; Simsek, Ibrahim; Nowak, David; Pfeiffelmann, Timo; Chen, Wenjian; Stroth, Christiane; Sayed, Mohamed; Mikolajczak, Ulf; Parisi, J.; Unold, Thomas; Mainz, Roland; Gütay, Levent

doi:10.1002/solr.202000124

Cited by 15 publications

(28 citation statements)

References 32 publications

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“…The amount and purities of the added reactants were 210 ± 2 mg of Se pellets (Mateck, 5N purity), 37.0 ± 0.4 mg of Sn wire (AlfaAesar, 4N purity, i.e., 10.0 ± 0.1 cm wire with 0.25 mm diameter) and, depending on the desired Ge addition, between 0 mg (reference process) and 110 ± 5 mg of Ge flakes (AlfaAesar, 5N purity). The reference process for synthesizing Ge-free absorbers is described in more detail elsewhere [11][12][13]. In brief, the Cu-rich and alloyed precursor layer (Zn/Cu-Sn/Zn) is annealed in presence of elemental Sn wire and Se pellets in a semi-closed graphite box.…”

Section: Methodsmentioning

confidence: 99%

“…In brief, the Ge is incorporated into the already-formed kesterite-absorber layer via the vapor phase during the high-temperature phase of the selenization process. During this step the composition of the layer is usually shifted from Cu-rich to Cu-poor [11,12]. Since the main kesterite phase formation route is unaltered, the process offers high reproducibility in terms of layer morphology and targeted final-layer composition.…”

Section: Introductionmentioning

confidence: 99%

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Vapor-Phase Incorporation of Ge in CZTSe Absorbers for Improved Stability of High-Efficiency Kesterite Solar Cells

et al. 2022

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We report an approach to incorporate Ge into Cu2ZnSnSe4 using GeSe vapor during the selenization step of alloyed metallic precursors. The vapor incorporation slowly begins at T ≈ 480 °C and peaks at 530 °C, resulting in a Ge-based composition shift inside the previously formed kesterite layer. We initially observe the formation of a Ge-rich surface layer that merges into a homogeneous distribution of the incorporated element during the further dwelling stage of the annealing. This approach is very versatile and could be used in many similar fabrication processes for incorporating Ge into CZTSe-absorber layers. Because the vapor-based composition shift in the layer happens after the formation of the absorber film towards the end of the fabrication process, most process parameters and the precursor structure may not need any significant re-optimization. The careful integration of this step could help to reduce Sn-related deep defects and accompanying VOC losses. The best CZTGSe-power-conversion efficiency obtained in this series is 10.4 % (with EG = 1.22 eV, FF = 54%, JSC = 36 mA/cm2, VOC = 540 mV, VOCdef,SQ = 417 mV). These results demonstrate the potential of this approach for Ge incorporation into kesterite absorbers.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Vapor-Phase Incorporation of Ge in CZTSe Absorbers for Improved Stability of High-Efficiency Kesterite Solar Cells

et al. 2022

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“…The group from Carl von Ossietzky University of Oldenburg also reported over 11% efficiency CZTSe solar cells based on Zn/Cu-Sn/Zn precursors with Sn-poor composition. [15,50,51] Their unique alloyed precursor with Zn on the top and unique growth process of shifting composition from Cu-rich (or Sn-poor) to Cu-poor (or Sn-sufficient) regime at high temperature provides a proper Zn-rich (relative to Sn) local chemical environment during the synthesis of CZTSe, [51] which may be attributable for their high-performance devices. However, with such growth process, precisely controlling the amount of Sn supply via SnSe 2−x vapor could be a challenge as over-supply of Sn may deteriorate the surface of CZTSe absorber by forming Sn Zn related defects and/or SnSe 2−x secondary phase.…”

Section: Cellmentioning

confidence: 99%

Defect Control for 12.5% Efficiency Cu₂ZnSnSe₄ Kesterite Thin‐Film Solar Cells by Engineering of Local Chemical Environment

et al. 2020

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over 30% detailed balance limiting efficiency, as well as to its earth-abundant and environment-benign constituents. [1-3] The increase in power conversion efficiency to a record of 12.6% in the last decade has demonstrated the huge potential of these materials. [4,5] However, as one of the most complicated compound semiconductors, kesterite has much more intricate defect chemistry than its counterparts, Cu(In,Ga)Se 2 (CIGS) and CdTe, [6-8] making the control of intrinsic defects a major challenge. Deep intrinsic defects like Sn Zn antisites and related [Cu Zn +Sn Zn ] clusters act as deep recombination centers, leading to the short carrier lifetime. [7,9,10] Additionally, the large population of defect clusters like [2Cu Zn +Sn Zn ] introduces considerable potential (i.e., band or electrostatic) fluctuation. [11] Consequently, the performance of CZTSSe solar cells are currently stagnated by the large open-circuit voltage (V OC) deficit. [12,13] To address the detrimental intrinsic defects and defect clusters in CZTSSe absorber, multiple strategies have been employed. As suggested by the first-principle calculations, the formation energy of intrinsic defects and Kesterite-based Cu 2 ZnSn(S,Se) 4 semiconductors are emerging as promising materials for low-cost, environment-benign, and high-efficiency thin-film photo voltaics. However, the current state-of-the-art Cu 2 ZnSn(S,Se) 4 devices suffer from cation-disordering defects and defect clusters, which generally result in severe potential fluctuation, low minority carrier lifetime, and ultimately unsatisfactory performance. Herein, critical growth conditions are reported for obtaining high-quality Cu 2 ZnSnSe 4 absorber layers with the formation of detrimental intrinsic defects largely suppressed. By controlling the oxidation states of cations and modifying the local chemical composition, the local chemical environment is essentially modified during the synthesis of kesterite phase, thereby effectively suppressing detrimental intrinsic defects and activating desirable shallow acceptor Cu vacancies. Consequently, a confirmed 12.5% efficiency is demonstrated with a high V OC of 491 mV, which is the new record efficiency of pure-selenide Cu 2 ZnSnSe 4 cells with lowest V OC deficit in the kesterite family by E g /q-Voc. These encouraging results demonstrate an essential route to overcome the long-standing challenge of defect control in kesterite semiconductors, which may also be generally applicable to other multinary compound semiconductors.

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“…The increase in the amount of Sn for the reference sample (i.e., 0 s) is found to be approximately 30% (from Cu/Sn = 2.4 to Cu/Sn = 1.89) and matches with the previously reported results. [ 11 ] As reported there, the expected absence of elemental Sn helps to avoid the formation of volatile Sn‐chalcogenides and promotes the kesterite formation mostly via ternary phase. The composition shift for the sample with additional Sn amount (324 s of sputtering, red circles) shows a reduction in Sn content by 13% (Cu/Sn = 1.4 toward Cu/Sn = 1.68), which occurs by evaporation of volatile Sn selenides.…”

Section: Resultsmentioning

confidence: 84%

“…In this study, we are exploring the possibilities of our previously reported growth process [ 11 ] and present the resulting device properties in composition maps of the as‐grown precursor and final absorber. Various degrees of in‐process composition shifts based on different starting Sn amounts in the precursor are investigated.…”

Section: Introductionmentioning

confidence: 99%

Tuning of Precursor Composition and Formation Pathway of Kesterite Absorbers Using an In‐Process Composition Shift: A Path toward Higher Efficiencies?

et al. 2021

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This work reports a growth process for tuning the formation pathway and final composition of kesterite Cu2ZnSnSe4 (CZTSe) thin film absorbers. By adjusting the as‐grown composition of the precursor, the kesterite formation can be started in a Cu‐rich, stoichiometric, or Cu‐poor environment. During the high‐temperature stage of the annealing process, incorporation or loss of SnSe2–x vapor at the layer is used to achieve an in‐process composition shift during further kesterite growth (e.g., Cu‐rich to Cu‐poor/Cu‐poor toward Cu‐rich). This approach partially decouples the composition of the as‐grown precursor and the final absorber, which, thus, can be tuned independently. The film growth, specifically the composition shift during the process, is tracked by interruption experiments. The influence of the starting composition of the precursor and the resulting absorber composition on the optoelectronic properties and device performance of the final solar cells is discussed. The results show a refined composition region for reduced Urbach tailing and lower V OC deficit. The best solar cells show efficiencies > 11% and a V OC deficit < 320 mV (relative to the Shockley–Queisser limit).

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Reaction Pathway for Efficient Cu₂ZnSnSe₄ Solar Cells from Alloyed CuSn Precursor via a Cu‐Rich Selenization Stage

Cited by 15 publications

References 32 publications

Vapor-Phase Incorporation of Ge in CZTSe Absorbers for Improved Stability of High-Efficiency Kesterite Solar Cells

Vapor-Phase Incorporation of Ge in CZTSe Absorbers for Improved Stability of High-Efficiency Kesterite Solar Cells

Defect Control for 12.5% Efficiency Cu₂ZnSnSe₄ Kesterite Thin‐Film Solar Cells by Engineering of Local Chemical Environment

Tuning of Precursor Composition and Formation Pathway of Kesterite Absorbers Using an In‐Process Composition Shift: A Path toward Higher Efficiencies?

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Reaction Pathway for Efficient Cu2ZnSnSe4 Solar Cells from Alloyed CuSn Precursor via a Cu‐Rich Selenization Stage

Cited by 15 publications

References 32 publications

Vapor-Phase Incorporation of Ge in CZTSe Absorbers for Improved Stability of High-Efficiency Kesterite Solar Cells

Vapor-Phase Incorporation of Ge in CZTSe Absorbers for Improved Stability of High-Efficiency Kesterite Solar Cells

Defect Control for 12.5% Efficiency Cu2ZnSnSe4 Kesterite Thin‐Film Solar Cells by Engineering of Local Chemical Environment

Tuning of Precursor Composition and Formation Pathway of Kesterite Absorbers Using an In‐Process Composition Shift: A Path toward Higher Efficiencies?

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Reaction Pathway for Efficient Cu₂ZnSnSe₄ Solar Cells from Alloyed CuSn Precursor via a Cu‐Rich Selenization Stage

Defect Control for 12.5% Efficiency Cu₂ZnSnSe₄ Kesterite Thin‐Film Solar Cells by Engineering of Local Chemical Environment