Monolithic Two-Terminal Perovskite/CIS Tandem Solar Cells with Efficiency Approaching 25%

Ruiz‐Preciado, Marco A.; Gota, Fabrizio; Faßl, Paul; Hossain, Ihteaz M.; Singh, Roja; Laufer, Felix; Schackmar, Fabian; Feeney, Thomas; Farag, Ahmed; Allegro, Isabel; Hu, Hang; Gharibzadeh, Saba; Nejand, Bahram Abdollahi; Gevaerts, Veronique S.; Šimor, Marcel; Bolt, P.J.; Paetzold, Ulrich W.

doi:10.1021/acsenergylett.2c00707

Cited by 59 publications

(51 citation statements)

References 53 publications

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“…Finally, the efficiency reported by this group was 31.13 % for the 2T Perovskite/CIGS tandem solar cell configuration. In June 2022, an international group of scientists headed by Dr. Preciado and Prof. W. Paetzold achieved a certified efficiency of 24.9 % utilizing perovskite/CIS tandem solar cells [23] . In a 2T tandem arrangement, this perovskite/CIS solar cell efficiency measurement is the highest one that has been published.…”

Section: Related Workmentioning

confidence: 86%

“…In June 2022, an international group of scientists headed by Dr. Preciado and Prof. W. Paetzold achieved a certified efficiency of 24.9 % utilizing perovskite/CIS tandem solar cells. [23] In a 2T tandem arrangement, this perovskite/CIS solar cell efficiency measurement is the highest one that has been published. By decreasing the quantity of gallium, it is possible to get a small band gap of around one electron volt (eV), which is quite near to the optimal value of 0.96 eV for the bottom solar cell in a tandem arrangement.…”

Section: Chemistryselectmentioning

confidence: 94%

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Computational Modelling and Optimization of a Methylammonium‐free Perovskite and Ga‐free Chalcogenide Tandem Solar Cell with an Efficiency above 25 %

2022

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Multi‐junction solar cells connecting two or more cells with significantly different bandgaps have a lot of promise for exceeding the Shockley Queisser (S‐Q) efficiency limit of single‐junction‐based photovoltaic devices. In this article, a new class of tandem devices has been proposed and investigated for improved efficiencies. The proposed tandem cell is connected in monolithic two‐terminal tandem configurations with wide bandgap formamidinium (FA) based perovskite absorber (FA0.85 Cs0.15 Pb (I0.85 Br0.15)3) (1.6 eV) (Cs15/Br15)) on the top cell and low bandgap gallium free chalcogenide (CuInSe2) absorber on the bottom cell. Doped FA‐based perovskite material is preferred over commonly used FAPbI3 as it is a proven fact that adding modest quantities of cesium and bromine stabilizes the optically active black phase of FAPbI3 Perovskite and increases overall device performance. In contrast, bottom CuInSe2 (CIS) absorber material is selected considering its good thermal stability and excellent light‐absorbing capabilities in a broad‐spectrum range. The feasibility of the suggested tandem configuration is assessed in two steps. First, a 1.6 eV perovskite top cell is simulated and calibrated to suit the state‐of‐the‐art power conversion efficiency of 17.5 %, followed by a 1.04 eV CuInSe2‐based bottom cell with a calibrated efficiency of 16.2 %. Both devices are tested for tandem configuration once the standalone (top and bottom) subcells have been calibrated. At varied absorber thicknesses in both the top and bottom subcells, the current matching conditions are achieved. At optimal thicknesses of 700 nm and 590 nm for the bottom and top absorbers, respectively, the overall tandem structure obtained an excellent power conversion efficiency of 25.13 %. Results reported in this study may pave the way for the development of high‐efficiency perovskite/CIS based tandem solar cells in the future.

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Section: Related Workmentioning

confidence: 86%

Section: Chemistryselectmentioning

confidence: 94%

Computational Modelling and Optimization of a Methylammonium‐free Perovskite and Ga‐free Chalcogenide Tandem Solar Cell with an Efficiency above 25 %

2022

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“…With regard to perovskite/CIGS tandem solar cells the development of new bandgap combinations, using narrow‐bandgap (≈1.01 eV) gallium‐free CIS bottom cells, lead to good performance of 23.5% certified. [ 35 ] In terms of scalability (see bottom‐right plot of Figure 3), only the new cells of Si/perovskite and CIGS/perovskite show promising areas equal/close to 1 cm 2 , whereas all other devices were tested with areas smaller than 0.1 cm 2 .…”

Section: Highest Efficiency Research Photovoltaic Cellsmentioning

confidence: 99%

“…The first‐ever monolithic CIS/perovskite tandem solar cell has been reported by Ruiz‐Preciado et al. [ 35 ] with a PCE exceeding 23% (23.5% certified, area: 0.5 cm 2 ). The relatively planar surface profile and narrow bandgap of the CIS bottom subcell allowed them to deposit perovskite top subcells of lower bandgap and with a smaller amount of bromide content, which is desirable to reduce photodegradation.…”

Section: Highest Efficiency Research Photovoltaic Cellsmentioning

confidence: 99%

Device Performance of Emerging Photovoltaic Materials (Version 3)

Almora

Baran

Bazan

et al. 2022

Advanced Energy Materials

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Following the 2nd release of the "Emerging PV reports," the best achievements in the performance of emerging photovoltaic devices in diverse emerging photovoltaic research subjects are summarized, as reported in peer-reviewed articles in academic journals since August 2021. Updated graphs, tables, and analyses are provided with several performance parameters, e.g., power conversion efficiency, open-circuit voltage, short-circuit current density, fill factor, light utilization efficiency, and stability test energy yield. These parameters are presented as a function of the photovoltaic bandgap energy and the average visible transmittance for each technology and application, and are put into perspective using, e.g., the detailed balance efficiency limit. The 3rd installment of the "Emerging PV reports" extends the scope toward triple junction solar cells.The ORCID identification number(s) for the author(s) of this article can be found under https://doi.org/10.1002/aenm.202203313.

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“…[1] Considering efficiency limitations imposed on singlejunction photovoltaic (PV) device performance by the Shockley-Queisser limit, any further increase in PCE is most easily achieved by tandem device architecture. [2][3][4][5][6][7] Due to the wide and tunable bandgap of the perovskite absorber, these semitransparent PSCs are typically employed as the top subcell [8] (%1.55-1.85 eV bandgap) paired with narrow-bandgap silicon, [3,6] copper indium gallium selenide (CIGS), [2,5] CIS [9] or tin-lead PSCs [10][11][12] as the bottom subcell. Within the current state of the art, these tandem devices utilize either a two-terminal (2T) or a four-terminal (4T) architecture.…”

mentioning

confidence: 99%

Four‐Terminal Perovskite/Copper Indium Gallium Selenide Tandem Solar Cells: Unveiling the Path to >27% in Power Conversion Efficiency

et al. 2022

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Over the past decade, the impressive progress in power conversion efficiency (PCE) of organometallic halide perovskite solar cells (PSCs), coupled with their ready integration into tandem solar cells, has led them to approach PCEs of 30% for tandem solar cells with a silicon bottom subcell. However, the complementary technology of perovskite/copper indium gallium selenide (CIGS) tandem solar cells has been thus far unable to reach similar efficiency values. Herein, a further advance in the efficiency of 4T perovskite/CIGS tandems is demonstrated, increasing the PCE up to 27.3% via systematic optimization of the top semitransparent PSC. Improvements in light management through the optimization of anti‐reflection coatings, coupled with the development of transparent conductive oxides that incur very low parasitic absorption are reported. It is revealed that both are crucial for maximizing efficiency and, by utilizing additional optical simulations, a detailed loss analysis that enables us to outline a path toward approaching 30% PCE for 4T perovskite/CIGS tandem devices is developed.

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Monolithic Two-Terminal Perovskite/CIS Tandem Solar Cells with Efficiency Approaching 25%

Cited by 59 publications

References 53 publications

Computational Modelling and Optimization of a Methylammonium‐free Perovskite and Ga‐free Chalcogenide Tandem Solar Cell with an Efficiency above 25 %

Computational Modelling and Optimization of a Methylammonium‐free Perovskite and Ga‐free Chalcogenide Tandem Solar Cell with an Efficiency above 25 %

Device Performance of Emerging Photovoltaic Materials (Version 3)

Four‐Terminal Perovskite/Copper Indium Gallium Selenide Tandem Solar Cells: Unveiling the Path to >27% in Power Conversion Efficiency

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