Your search keyword '"Bracesco, Andrea"' showing total 31 results

1. In Situ IR Spectroscopy Studies of Atomic Layer-Deposited SnO2 on Fullerenes for Perovskite Photovoltaics.

Author

Bracesco, Andrea E. A., van Himste, Joost, Kessels, Wilhelmus M. M., Zardetto, Valerio, and Creatore, Mariadriana

Published

2024

2. In Situ IR Spectroscopy Studies of Atomic Layer-Deposited SnO2on Fullerenes for Perovskite Photovoltaics

Author

Bracesco, Andrea E. A., van Himste, Joost, Kessels, Wilhelmus M. M., Zardetto, Valerio, and Creatore, Mariadriana

Abstract

In recent years, atomic layer deposition (ALD) has established itself as the state-of-the-art technique for the deposition of SnO2buffer layers grown between the fullerene electron transport layer (ETL) and the ITO top electrode in metal halide perovskite-based photovoltaics. The SnO2layer shields the underlying layers, i.e., the fullerene-derivative materials such as C60 and PCBM, as well as the perovskite absorber, from water ingress and damage induced by the sputtering of the transparent front contact. Our study undertakes a comprehensive investigation of the impact of SnO2ALD processing on fullerenes by means of in situspectroscopic ellipsometry (SE) and transmission infrared spectroscopy (FTIR). While no difference in SnO2bulk properties is observed and the perovskite absorber degradation is nearly entirely avoided during exposure to heat and vacuum, when the absorber is introduced beneath the organic ETLs, a SnO2growth delay of about 50 ALD cycles is measured on PCBM, whereas the delay is limited to 10 cycles in the case of growth on C60. Notably, FTIR measurements show that while C60 remains chemically unaffected during SnO2ALD growth, PCBM undergoes chemical modification, specifically of its ester groups. The onset of these modifications corresponds with the detection of the onset, after the initial delay, of ALD SnO2growth. It is expected that the modification that the PCBM layer undergoes upon ALD SnO2processing is responsible for the systematic lower photovoltaic device performance in the case of PCBM-based devices, with respect to C60-based devices.

Published

2024

3. Growth Mechanism and Film Properties of Atomic-Layer-Deposited Titanium Oxysulfide

Author

Macco, Bart, primary, van Kasteren, Jeroen, additional, Basuvalingam, Saravana Balaji, additional, Mattinen, Miika, additional, Bracesco, Andrea, additional, Kessels, Wilhelmus M. M. (Erwin), additional, and Bol, Ageeth, additional

Published

2023

4. Low Damage Scalable Pulsed Laser Deposition of SnO2 for p–i–n Perovskite Solar Cells

Author

Soltanpoor, Wiria, primary, Bracesco, Andrea E. A., additional, Rodkey, Nathan, additional, Creatore, Mariadriana, additional, and Morales-Masis, Monica, additional

Published

2023

5. Surface Modulation via Conjugated Bithiophene Ammonium Salt for Efficient Inverted Perovskite Solar Cells

Author

Zhang, Xin, primary, Eurelings, Stijn, additional, Bracesco, Andrea, additional, Song, Wenya, additional, Lenaers, Stijn, additional, Van Gompel, Wouter, additional, Krishna, Anurag, additional, Aernouts, Tom, additional, Lutsen, Laurence, additional, Vanderzande, Dirk, additional, Creatore, Mariadriana, additional, Zhan, Yiqiang, additional, Kuang, Yinghuan, additional, and Poortmans, Jef, additional

Published

2023

6. In Situ IR Spectroscopy Studies of Atomic Layer-Deposited SnO2 on Formamidinium-Based Lead Halide Perovskite

Author

Bracesco, Andrea E. A., primary, Jansen, Jarvi W. P, additional, Xue, Haibo, additional, Zardetto, Valerio, additional, Brocks, Geert, additional, Kessels, Wilhelmus M. M., additional, Tao, Shuxia, additional, and Creatore, Mariadriana, additional

Published

2023

7. Minimizing the Interface-Driven Losses in Inverted Perovskite Solar Cells and Modules

Author

Zhang, Xin, primary, Qiu, Weiming, additional, Apergi, Sofia, additional, Singh, Shivam, additional, Marchezi, Paulo, additional, Song, Wenya, additional, Sternemann, Christian, additional, Elkhouly, Karim, additional, Zhang, Dong, additional, Aguirre, Aranzazu, additional, Merckx, Tamara, additional, Krishna, Anurag, additional, Shi, Yuanyuan, additional, Bracesco, Andrea, additional, van Helvoirt, Cristian, additional, Bens, Frennie, additional, Zardetto, Valerio, additional, D’Haen, Jan, additional, Yu, Anran, additional, Brocks, Geert, additional, Aernouts, Tom, additional, Moons, Ellen, additional, Tao, Shuxia, additional, Zhan, Yiqiang, additional, Kuang, Yinghuan, additional, and Poortmans, Jef, additional

Published

2023

8. Optical Simulation-Aided Design and Engineering of Monolithic Perovskite/Silicon Tandem Solar Cells

Author

Zhao, Yifeng, primary, Datta, Kunal, additional, Phung, Nga, additional, Bracesco, Andrea E. A., additional, Zardetto, Valerio, additional, Paggiaro, Giulia, additional, Liu, Hanchen, additional, Fardousi, Mohua, additional, Santbergen, Rudi, additional, Moya, Paul Procel, additional, Han, Can, additional, Yang, Guangtao, additional, Wang, Junke, additional, Zhang, Dong, additional, van Gorkom, Bas T., additional, van der Pol, Tom P. A., additional, Verhage, Michael, additional, Wienk, Martijn M., additional, Kessels, Wilhelmus M. M., additional, Weeber, Arthur, additional, Zeman, Miro, additional, Mazzarella, Luana, additional, Creatore, Mariadriana, additional, Janssen, René A. J., additional, and Isabella, Olindo, additional

Published

2023

9. Low Damage Scalable Pulsed Laser Deposition of SnO2 for p–i–n Perovskite Solar Cells

Author

Soltanpoor, Wiria, Bracesco, Andrea E.A., Rodkey, Nathan, Creatore, Mariadriana, Morales-Masis, Monica, Soltanpoor, Wiria, Bracesco, Andrea E.A., Rodkey, Nathan, Creatore, Mariadriana, and Morales-Masis, Monica

Abstract

Pulsed laser deposition (PLD) has already been adopted as a low damage deposition technique of transparent conducting oxides on top of sensitive organic charge transport layers in optoelectronic devices. Herein, SnO2 deposition is demonstrated as buffer layer in p–i–n perovskite solar cells (PSCs) via wafer-scale (4 inch) PLD at room temperature. The PLD SnO2 properties, its interface with perovskite/C60, and device performance are compared to atomic layer deposited (ALD) SnO2, i.e., state-of-the-art buffer layer in perovskite-based single junction and tandem photovoltaics. The PLD SnO2-based solar cells exhibit on par efficiencies (17.8%) with that of SnO2 fabricated using ALD. The solvent-free room temperature processing and wafer-scale approach of PLD open up possibilities for buffer layer formation with increased deposition rates while mitigating potential thermal or physical damage to the top organic layers. This is a promising outlook for fully physical vapor-processed halide PSCs and optoelectronic devices requiring low thermal budget.

Published

2023

10. Minimizing the Interface-Driven Losses in Inverted Perovskite Solar Cells and Modules

Author

Zhang, Xin, Qiu, Weiming, Apergi, Sofia, Singh, Shivam, Marchezi, Paulo, Song, Wenya, Sternemann, Christian, Elkhouly, Karim, Zhang, Dong, Aguirre, Aranzazu, Merckx, Tamara, Krishna, Anurag, Shi, Yuanyuan, Bracesco, Andrea, van Helvoirt, Cristian, Bens, Frennie, Zardetto, Valerio, D’Haen, Jan, Yu, Anran, Brocks, Geert, Aernouts, Tom, Moons, Ellen, Tao, Shuxia, Zhan, Yiqiang, Kuang, Yinghuan, Poortmans, Jef, Zhang, Xin, Qiu, Weiming, Apergi, Sofia, Singh, Shivam, Marchezi, Paulo, Song, Wenya, Sternemann, Christian, Elkhouly, Karim, Zhang, Dong, Aguirre, Aranzazu, Merckx, Tamara, Krishna, Anurag, Shi, Yuanyuan, Bracesco, Andrea, van Helvoirt, Cristian, Bens, Frennie, Zardetto, Valerio, D’Haen, Jan, Yu, Anran, Brocks, Geert, Aernouts, Tom, Moons, Ellen, Tao, Shuxia, Zhan, Yiqiang, Kuang, Yinghuan, and Poortmans, Jef

Abstract

The inverted p-i-n perovskite solar cells hold high promise for scale-up toward commercialization. However, the interfaces between the perovskite and the charge transport layers contribute to major power conversion efficiency (PCE) loss and instability. Here, we use a single material of 2-thiopheneethylammonium chloride (TEACl) to molecularly engineer both the interface between the perovskite and fullerene-C60 electron transport layer and the buried interface between the perovskite and NiOx-based hole transport layer. The dual interface modification results in optimized band alignment, suppressed nonradiative recombination, and improved interfacial contact. A PCE of 24.3% is demonstrated, with open-circuit voltage (Voc) and fill factor (FF) of 1.17 V and 84.6%, respectively. The unencapsulated device retains >97.0% of the initial performance after 1000 h of maximum power point tracking under illumination. Moreover, a PCE of 22.6% and a remarkable FF of 82.4% are obtained for a mini-module with an active area of 3.63

Published

2023

11. In Situ IR SpectroscopyStudies of AtomicLayer-Deposited SnO2 on Formamidinium-Based Lead Halide Perovskite

Author

Bracesco, Andrea, Jansen, Jarvi W.P., Xue, Haibo, Zardetto, V., Brocks, Geert H.L.A., Kessels, W.M.M., Tao, Shuxia, Creatore, M., Bracesco, Andrea, Jansen, Jarvi W.P., Xue, Haibo, Zardetto, V., Brocks, Geert H.L.A., Kessels, W.M.M., Tao, Shuxia, and Creatore, M.

Abstract

Perovskite photovoltaics has achieved conversion efficiencies of 26.0% by optimizing the optoelectronic properties of the absorber and its interfaces with charge transport layers (CTLs). However, commonly adopted organic CTLs can lead to parasitic absorption and device instability. Therefore, metal oxides like atomic layer-deposited (ALD) SnO2 in combination with fullerene-based electron transport layers have been introduced to enhance mechanical and thermal stability. Instead, when ALD SnO2 is directly processed on the absorber, i.e., without the fullerene layer, chemical modifications of the inorganic fraction of the perovskite occur, compromising the device performance. This study focuses on the organic fraction, particularly the formamidinium cation (FA+), in a CsFAPb(I,Br)3 perovskite. By employing in situ infrared spectroscopy, we investigate the impact of ALD processing on the perovskite, such as vacuum level, temperature, and exposure to half and full ALD cycles using tetrakis(dimethylamido)-Sn(IV) (TDMA-Sn) and H2O. We observe that exposing the absorber to vacuum conditions or water half-cycles has a negligible effect on the chemistry of the perovskite. However, prolonged exposure at 100 °C for 90 min results in a loss of 0.7% of the total formamidinium-related vibrational features compared to the pristine perovskite. Supported by density functional theory calculations, we speculate that FA+ deprotonates and that formamidine desorbs from the perovskite surface. Furthermore, the interaction between TDMA-Sn and FA+ induces more decomposition of the perovskite surface compared to vacuum, temperature, or H2O exposure. During the exposure to 10 ALD half-cycles of TDMA-Sn, 4% of the total FA+-related infrared features are lost compared to the pristine perovskite. Additionally, IR spectroscopy suggests the formation and trapping of sym-triazine, i.e., a decomposition product of FA+. These studies enable to decouple the effects occurring during direct ALD processin

Published

2023

12. Crystalline silicon solar cells with thin poly-SiOx carrier-selective passivating contacts for perovskite/c-Si tandem applications

Author

Singh, Manvika, Datta, Kunal, Amarnath, Aswathy, Wagner, Fabian, Zhao, Yifeng, Yang, Guangtao, Bracesco, Andrea, Phung, Nga, Zhang, Dong, Zardetto, Valerio, Najafi, Mehrdad, Veenstra, Sjoerd C., Coletti, Gianluca, Mazzarella, Luana, Creatore, Mariadriana, Wienk, Martijn M., Janssen, René A.J., Weeber, Arthur W., Zeman, Miro, Isabella, Olindo, Singh, Manvika, Datta, Kunal, Amarnath, Aswathy, Wagner, Fabian, Zhao, Yifeng, Yang, Guangtao, Bracesco, Andrea, Phung, Nga, Zhang, Dong, Zardetto, Valerio, Najafi, Mehrdad, Veenstra, Sjoerd C., Coletti, Gianluca, Mazzarella, Luana, Creatore, Mariadriana, Wienk, Martijn M., Janssen, René A.J., Weeber, Arthur W., Zeman, Miro, and Isabella, Olindo

Abstract

Single junction crystalline silicon (c-Si) solar cells are reaching their practical efficiency limit whereas perovskite/c-Si tandem solar cells have achieved efficiencies above the theoretical limit of single junction c-Si solar cells. Next to low-thermal budget silicon heterojunction architecture, high-thermal budget carrier-selective passivating contacts (CSPCs) based on polycrystalline-SiOx (poly-SiOx) also constitute a promising architecture for high efficiency perovskite/c-Si tandem solar cells. In this work, we present the development of c-Si bottom cells based on high temperature poly-SiOx CSPCs and demonstrate novel high efficiency four-terminal (4T) and two-terminal (2T) perovskite/c-Si tandem solar cells. First, we tuned the ultra-thin, thermally grown SiOx. Then we optimized the passivation properties of p-type and n-type doped poly-SiOx CSPCs. Here, we have optimized the p-type doped poly-SiOx CSPC on textured interfaces via a two-step annealing process. Finally, we integrated such bottom solar cells in both 4T and 2T tandems, achieving 28.1% and 23.2% conversion efficiency, respectively.

Published

2023

13. Optical Simulation-Aided Design and Engineering of Monolithic Perovskite/Silicon Tandem Solar Cells

Author

Zhao, Yifeng, Datta, Kunal, Phung, Nga, Bracesco, Andrea E.A., Zardetto, Valerio, Paggiaro, Giulia, Liu, Hanchen, Fardousi, Mohua, Santbergen, Rudi, Procel Moya, Paul, Han, Can, Yang, Guangtao, Wang, Junke, Zhang, Dong, van Gorkom, Bas T., van der Pol, Tom P.A., Verhage, Michael, Wienk, Martijn M., Kessels, W.M.M., Weeber, Arthur, Zeman, Miro, Mazzarella, Luana, Creatore, Mariadriana, Janssen, René A.J., Isabella, Olindo, Zhao, Yifeng, Datta, Kunal, Phung, Nga, Bracesco, Andrea E.A., Zardetto, Valerio, Paggiaro, Giulia, Liu, Hanchen, Fardousi, Mohua, Santbergen, Rudi, Procel Moya, Paul, Han, Can, Yang, Guangtao, Wang, Junke, Zhang, Dong, van Gorkom, Bas T., van der Pol, Tom P.A., Verhage, Michael, Wienk, Martijn M., Kessels, W.M.M., Weeber, Arthur, Zeman, Miro, Mazzarella, Luana, Creatore, Mariadriana, Janssen, René A.J., and Isabella, Olindo

Abstract

Monolithic perovskite/c-Si tandem solar cells have attracted enormous research attention and have achieved efficiencies above 30%. This work describes the development of monolithic tandem solar cells based on silicon heterojunction (SHJ) bottom- and perovskite top-cells and highlights light management techniques assisted by optical simulation. We first engineered (i)a-Si:H passivating layers for (100)-oriented flat c-Si surfaces and combined them with various (n)a-Si:H, (n)nc-Si:H, and (n)nc-SiOx:H interfacial layers for SHJ bottom-cells. In a symmetrical configuration, a long minority carrier lifetime of 16.9 ms was achieved when combining (i)a-Si:H bilayers with (n)nc-Si:H (extracted at the minority carrier density of 1015 cm–3). The perovskite sub-cell uses a photostable mixed-halide composition and surface passivation strategies to minimize energetic losses at charge-transport interfaces. This allows tandem efficiencies above 23% (a maximum of 24.6%) to be achieved using all three types of (n)-layers. Observations from experimentally prepared devices and optical simulations indicate that both (n)nc-SiOx:H and (n)nc-Si:H are promising for use in high-efficiency tandem solar cells. This is possible due to minimized reflection at the interfaces between the perovskite and SHJ sub-cells by optimized interference effects, demonstrating the applicability of such light management techniques to various tandem structures.

Published

2023

14. Efficient Continuous Light-Driven Electrochemical Water Splitting Enabled by Monolithic Perovskite-Silicon Tandem Photovoltaics

Author

Datta, Kunal, Branco, Bruno, Zhao, Yifeng, Zardetto, Valerio, Phung, Nga, Bracesco, Andrea, Mazzarella, Luana, Wienk, Martijn M., Creatore, Mariadriana, Isabella, Olindo, Janssen, René A.J., Datta, Kunal, Branco, Bruno, Zhao, Yifeng, Zardetto, Valerio, Phung, Nga, Bracesco, Andrea, Mazzarella, Luana, Wienk, Martijn M., Creatore, Mariadriana, Isabella, Olindo, and Janssen, René A.J.

Abstract

Solar-assisted water electrolysis is a promising technology for storing the energy of incident solar irradiation into hydrogen as a fuel. Here, an integrated continuous flow electrochemical reactor coupled to a monolithic perovskite-silicon tandem solar cell is demonstrated that provides light-driven electrochemical solar-to-hydrogen conversion with an energy conversion efficiency exceeding 21% at 1-Sun equivalent light intensity and stable operation during three simulated day-night cycles.

Published

2023

15. Surface Modulation via Conjugated Bithiophene Ammonium Salt for Efficient Inverted Perovskite Solar Cells

Author

Zhang, Xin, Eurelings, Stijn S.E., Bracesco, Andrea, Song, Wenya, Lenaers, Stijn, van Gompel, Wouter T.M., Krishna, Anurag, Aernouts, Tom, Lutsen, Laurence, Vanderzande, Dirk J.M., Creatore, M., Zhan, Yiqiang, Kuang, Yinghuan, Poortmans, Jef, Zhang, Xin, Eurelings, Stijn S.E., Bracesco, Andrea, Song, Wenya, Lenaers, Stijn, van Gompel, Wouter T.M., Krishna, Anurag, Aernouts, Tom, Lutsen, Laurence, Vanderzande, Dirk J.M., Creatore, M., Zhan, Yiqiang, Kuang, Yinghuan, and Poortmans, Jef

Abstract

The metal halide perovskite absorbers are prone to surface defects, which severely limit the power conversion efficiencies (PCEs) and the operational stability of the perovskite solar cells (PSCs). Herein, trace amounts of bithiophene propylammonium iodide (bi-TPAI) are applied to modulate the surface properties of the gas-quenched perovskite. It is found that the bi-TPAI surface treatment has negligible impact on the perovskite morphology, but it can induce a defect passivation effect and facilitate the charge carrier extraction, contributing to the gain in the open-circuit voltage (Voc) and fill factor. As a result, the PCE of the gas-quenched sputtered NiOx-based inverted PSCs is enhanced from the initial 20.0% to 22.0%. Most importantly, the bi-TPAI treatment can largely alleviate or even eliminate the burn-in process during the maximum power point tracking measurement, improving the operational stability of the devices.

Published

2023

16. Low Damage Scalable Pulsed Laser Deposition of SnO2 for p–i–n Perovskite Solar Cells.

Author

Soltanpoor, Wiria, Bracesco, Andrea E. A., Rodkey, Nathan, Creatore, Mariadriana, and Morales-Masis, Monica

Subjects

PULSED laser deposition, OPTOELECTRONIC devices, SOLAR cells, BUFFER layers, PEROVSKITE, STANNIC oxide

Abstract

Pulsed laser deposition (PLD) has already been adopted as a low damage deposition technique of transparent conducting oxides on top of sensitive organic charge transport layers in optoelectronic devices. Herein, SnO2 deposition is demonstrated as buffer layer in p–i–n perovskite solar cells (PSCs) via wafer‐scale (4 inch) PLD at room temperature. The PLD SnO2 properties, its interface with perovskite/C60, and device performance are compared to atomic layer deposited (ALD) SnO2, i.e., state‐of‐the‐art buffer layer in perovskite‐based single junction and tandem photovoltaics. The PLD SnO2‐based solar cells exhibit on par efficiencies (17.8%) with that of SnO2 fabricated using ALD. The solvent‐free room temperature processing and wafer‐scale approach of PLD open up possibilities for buffer layer formation with increased deposition rates while mitigating potential thermal or physical damage to the top organic layers. This is a promising outlook for fully physical vapor‐processed halide PSCs and optoelectronic devices requiring low thermal budget. [ABSTRACT FROM AUTHOR]

Published

2023

17. Crystalline silicon solar cells with thin poly‐SiOx carrier‐selective passivating contacts for perovskite/c‐Si tandem applications

Author

Singh, Manvika, primary, Datta, Kunal, additional, Amarnath, Aswathy, additional, Wagner, Fabian, additional, Zhao, Yifeng, additional, Yang, Guangtao, additional, Bracesco, Andrea, additional, Phung, Nga, additional, Zhang, Dong, additional, Zardetto, Valerio, additional, Najafi, Mehrdad, additional, Veenstra, Sjoerd C., additional, Coletti, Gianluca, additional, Mazzarella, Luana, additional, Creatore, Mariadriana, additional, Wienk, Martijn M., additional, Janssen, René A. J., additional, Weeber, Arthur W., additional, Zeman, Miro, additional, and Isabella, Olindo, additional

Published

2023

18. Crystalline silicon solar cells with thin poly-SiO x carrier-selective passivating contacts for perovskite/c-Si tandem applications

Author

Singh, Manvika, primary, Datta, Kunal, additional, Amarnath, Aswathy, additional, Wagner, Fabian, additional, Zhao, Yifeng, additional, Yang, Guangtao, additional, Bracesco, Andrea, additional, Phung, Nga, additional, Zhang, Dong, additional, Zardetto, Valerio, additional, Najafi, Mehrdad, additional, Veenstra, Sjoerd C., additional, Coletti, Dr. Gianluca, additional, Mazzarella, Luana, additional, creatore, mariadriana, additional, Wienk, Martijn M., additional, Janssen, Rene, additional, Weber, Arthur, additional, Zeman, Miro, additional, and Isabella, Olindo, additional

Published

2023

19. Efficient Continuous Light‐Driven Electrochemical Water Splitting Enabled by Monolithic Perovskite‐Silicon Tandem Photovoltaics

Author

Datta, Kunal, primary, Branco, Bruno, additional, Zhao, Yifeng, additional, Zardetto, Valerio, additional, Phung, Nga, additional, Bracesco, Andrea, additional, Mazzarella, Luana, additional, Wienk, Martijn M., additional, Creatore, Mariadriana, additional, Isabella, Olindo, additional, and Janssen, René A. J., additional

Published

2022

20. Crystalline silicon solar cells with thin poly‐SiOx carrier‐selective passivating contacts for perovskite/c‐Si tandem applications.

Author

Singh, Manvika, Datta, Kunal, Amarnath, Aswathy, Wagner, Fabian, Zhao, Yifeng, Yang, Guangtao, Bracesco, Andrea, Phung, Nga, Zhang, Dong, Zardetto, Valerio, Najafi, Mehrdad, Veenstra, Sjoerd C., Coletti, Gianluca, Mazzarella, Luana, Creatore, Mariadriana, Wienk, Martijn M., Janssen, René A. J., Weeber, Arthur W., Zeman, Miro, and Isabella, Olindo

Subjects

PHOTOVOLTAIC power systems, SILICON solar cells, SOLAR cells

Abstract

Single junction crystalline silicon (c‐Si) solar cells are reaching their practical efficiency limit whereas perovskite/c‐Si tandem solar cells have achieved efficiencies above the theoretical limit of single junction c‐Si solar cells. Next to low‐thermal budget silicon heterojunction architecture, high‐thermal budget carrier‐selective passivating contacts (CSPCs) based on polycrystalline‐SiOx (poly‐SiOx) also constitute a promising architecture for high efficiency perovskite/c‐Si tandem solar cells. In this work, we present the development of c‐Si bottom cells based on high temperature poly‐SiOx CSPCs and demonstrate novel high efficiency four‐terminal (4T) and two‐terminal (2T) perovskite/c‐Si tandem solar cells. First, we tuned the ultra‐thin, thermally grown SiOx. Then we optimized the passivation properties of p‐type and n‐type doped poly‐SiOx CSPCs. Here, we have optimized the p‐type doped poly‐SiOx CSPC on textured interfaces via a two‐step annealing process. Finally, we integrated such bottom solar cells in both 4T and 2T tandems, achieving 28.1% and 23.2% conversion efficiency, respectively. [ABSTRACT FROM AUTHOR]

Published

2023

21. In Situ IR Spectroscopy Studies of Atomic Layer-Deposited SnO2 on Formamidinium-Based Lead Halide Perovskite.

Author

Bracesco, Andrea E. A., Jansen, Jarvi W. P, Xue, Haibo, Zardetto, Valerio, Brocks, Geert, Kessels, Wilhelmus M. M., Tao, Shuxia, and Creatore, Mariadriana

Published

2023

22. Growth Mechanism and Film Properties of Atomic-Layer-Deposited Titanium Oxysulfide

Author

van Kasteren, Jeroen G. A., primary, Basuvalingam, Saravana B., additional, Mattinen, Miika, additional, Bracesco, Andrea E. A., additional, Kessels, Wilhelmus M. M., additional, Bol, Ageeth A., additional, and Macco, Bart, additional

Published

2022

23. Growth Mechanism and Film Properties of Atomic-Layer-Deposited Titanium Oxysulfide

Author

van Kasteren, Jeroen G.A., Basuvalingam, Saravana B., Mattinen, Miika, Bracesco, Andrea E.A., Kessels, Wilhelmus M.M., Bol, Ageeth A., Macco, Bart, van Kasteren, Jeroen G.A., Basuvalingam, Saravana B., Mattinen, Miika, Bracesco, Andrea E.A., Kessels, Wilhelmus M.M., Bol, Ageeth A., and Macco, Bart

Abstract

In this work, atomic layer deposition (ALD) has been employed to prepare titanium oxysulfide (TiOxSy) thin films. Compositional control was achieved through a supercycle approach, where the ALD processes of TiOx and TiSx were interleaved. ALD was performed at 100, 150, and 200 °C, and tetrakis(dimethylamino)titanium (TDMAT), H2S, and H2O were used as precursors. It is shown that the conductivity and transparency of the film are highly tunable by controlling the composition of TiOxSy between pure TiSx and TiOx. Specifically, the incorporation of S enables the film resistivity to be reduced by up to 6 orders of magnitude, while the visible light absorption is increased significantly. It is furthermore shown that the resulting films are significantly more oxygen-rich than would be expected on the basis of the supercycle ratio, an effect which is more pronounced at higher deposition temperatures. Through mass spectrometry and in situ ellipsometry studies, this low S content is shown to originate from exchange reactions where S is replaced by O on the growth (sub)surface during H2O exposure. This is contrary to the common finding for ALD zinc, indium, and tin oxysulfide films, for which exchange reactions are known to favor S-rich films. These exchange reactions are shown to be more prominent at higher deposition temperatures and to persist until approximately 3–5 Å of TiOx has formed.

Published

2022

24. Efficient Continuous Light-Driven Electrochemical Water Splitting Enabled by Monolithic Perovskite-Silicon Tandem Photovoltaics

Author

Datta, Kunal (author), Branco, Bruno (author), Zhao, Y. (author), Zardetto, Valerio (author), Phung, Nga (author), Bracesco, Andrea (author), Mazzarella, L. (author), Wienk, Martijn M. (author), Isabella, O. (author), Datta, Kunal (author), Branco, Bruno (author), Zhao, Y. (author), Zardetto, Valerio (author), Phung, Nga (author), Bracesco, Andrea (author), Mazzarella, L. (author), Wienk, Martijn M. (author), and Isabella, O. (author)

Abstract

Solar-assisted water electrolysis is a promising technology for storing the energy of incident solar irradiation into hydrogen as a fuel. Here, an integrated continuous flow electrochemical reactor coupled to a monolithic perovskite-silicon tandem solar cell is demonstrated that provides light-driven electrochemical solar-to-hydrogen conversion with an energy conversion efficiency exceeding 21% at 1-Sun equivalent light intensity and stable operation during three simulated day-night cycles., Photovoltaic Materials and Devices

Published

2022

25. In Situ IR Spectroscopy Studies of Atomic Layer-Deposited SnO2on Formamidinium-Based Lead Halide Perovskite

Author

Bracesco, Andrea E. A., Jansen, Jarvi W. P, Xue, Haibo, Zardetto, Valerio, Brocks, Geert, Kessels, Wilhelmus M. M., Tao, Shuxia, and Creatore, Mariadriana

Abstract

Perovskite photovoltaics has achieved conversion efficiencies of 26.0% by optimizing the optoelectronic properties of the absorber and its interfaces with charge transport layers (CTLs). However, commonly adopted organic CTLs can lead to parasitic absorption and device instability. Therefore, metal oxides like atomic layer-deposited (ALD) SnO2in combination with fullerene-based electron transport layers have been introduced to enhance mechanical and thermal stability. Instead, when ALD SnO2is directly processed on the absorber, i.e., without the fullerene layer, chemical modifications of the inorganic fraction of the perovskite occur, compromising the device performance. This study focuses on the organic fraction, particularly the formamidinium cation (FA+), in a CsFAPb(I,Br)3perovskite. By employing in situ infrared spectroscopy, we investigate the impact of ALD processing on the perovskite, such as vacuum level, temperature, and exposure to half and full ALD cycles using tetrakis(dimethylamido)-Sn(IV) (TDMA-Sn) and H2O. We observe that exposing the absorber to vacuum conditions or water half-cycles has a negligible effect on the chemistry of the perovskite. However, prolonged exposure at 100 °C for 90 min results in a loss of 0.7% of the total formamidinium-related vibrational features compared to the pristine perovskite. Supported by density functional theory calculations, we speculate that FA+deprotonates and that formamidine desorbs from the perovskite surface. Furthermore, the interaction between TDMA-Sn and FA+induces more decomposition of the perovskite surface compared to vacuum, temperature, or H2O exposure. During the exposure to 10 ALD half-cycles of TDMA-Sn, 4% of the total FA+-related infrared features are lost compared to the pristine perovskite. Additionally, IR spectroscopy suggests the formation and trapping of sym-triazine, i.e., a decomposition product of FA+. These studies enable to decouple the effects occurring during direct ALD processing on the perovskite and highlight the crucial role of the Sn precursor in affecting the perovskite surface chemistry and compromising the device performance.

Published

2023

26. Step-by-step approach towards stable, semi-transparent, bifacial, rigid and flexible perovskite solar modules

Author

Veenstra, Sjoerd, primary, Andriessen, Ronn, additional, Zardetto, Valerio, additional, Simurka, Lukas, additional, Fledderus, Henri, additional, Verhees, Wiljan, additional, Zhang, Dong, additional, Najafi, Mehrdad, additional, Doğan, İlker, additional, Manshanden, Petra, additional, Bracesco, Andrea, additional, Aguirre, Aranzazu, additional, Galagan, Yulia, additional, Aernouts, Tom, additional, Creatore, Mariadriana, additional, and Lucarelli, Giulia, additional

Published

2022

27. The chemistry and energetics of the interface between metal halide perovskite and atomic layer deposited metal oxides

Author

Bracesco, Andrea E. A., primary, Burgess, Claire H., additional, Todinova, Anna, additional, Zardetto, Valerio, additional, Koushik, Dibyashree, additional, Kessels, Wilhelmus M. M (Erwin), additional, Dogan, Ilker, additional, Weijtens, Christ H. L., additional, Veenstra, Sjoerd, additional, Andriessen, Ronn, additional, and Creatore, Mariadriana, additional

Published

2020

28. The chemistry and energetics of the interface between metal halide perovskite and atomic layer deposited metal oxides

Author

Bracesco, Andrea, Burgess, Claire H., Todinova, Anna, Zardetto, V., Koushik, Dibyashree, Kessels, W.M.M., Dogan, I., Weijtens, Christ H.L., Veenstra, Sjoerd C., Andriessen, H.A.J.M. (Ronn), Creatore, M., Bracesco, Andrea, Burgess, Claire H., Todinova, Anna, Zardetto, V., Koushik, Dibyashree, Kessels, W.M.M., Dogan, I., Weijtens, Christ H.L., Veenstra, Sjoerd C., Andriessen, H.A.J.M. (Ronn), and Creatore, M.

Abstract

The chemistry of the interface between the metal halide perovskite absorber and the charge transport layer affects the performance and stability of metal halide perovskite solar cells (PSCs). The literature provides several examples of poor PSC conversion efficiency values, when electron transport layers (ETLs), such as SnO2 and TiO2, are processed by atomic layer deposition (ALD) directly on the perovskite absorber. In the present work, we shed light on the chemical modifications occurring at the perovskite surface, during ALD processing of SnO2 and TiO2, in parallel with the evaluation of the PSC cell performance. The ALD processes are carried out on a (Cs,FA)Pb(I,Br)3 perovskite by adopting tetrakis(dimethylamino)tin(IV) and tetrakis(dimethylamino)titanium(IV) as metal precursors and H2O as the coreactant for SnO2 and TiO2, respectively. Perovskite surface modification occurs in the form of an ultrathin PbBr2 layer. Furthermore, in the case of SnO2, halogen molecules are detected at the interface, in parallel with the initial growth of an oxygen-deficient SnO2. Subgap defect states just above the valence band maximum of SnO2 are also detected. These states act as hole traps at the perovskite/SnO2 interface, subsequently promoting charge recombination and deteriorating the performance of the cell. We hypothesize that a redox reaction between the perovskite, or its decomposition products, and the Sn metal center of the ALD precursor takes place: I− and Br− are oxidized to I2 and Br2, respectively, and Sn(IV) is reduced to Sn(II). In contrast, the Ti(IV) metal center does not undergo any redox process, and, as a result, a promising 11% power conversion efficiency is measured with TiO2 as the ETL. This result strongly suggests that TiO2 may be a more suitable ETL, when processed directly on the perovskite absorber.

Published

2020

29. Interface Engineering for Highly Efficient Perovskite Photovoltaics.

Author

Phung, Nga, Bracesco, Andrea, and Creatore, Mariadriana

Published

2023

30. In Situ IR Spectroscopy Studies of Atomic Layer-Deposited SnO 2 on Fullerenes for Perovskite Photovoltaics.

Author

Bracesco AEA, van Himste J, Kessels WMM, Zardetto V, and Creatore M

Abstract

In recent years, atomic layer deposition (ALD) has established itself as the state-of-the-art technique for the deposition of SnO 2 buffer layers grown between the fullerene electron transport layer (ETL) and the ITO top electrode in metal halide perovskite-based photovoltaics. The SnO 2 layer shields the underlying layers, i.e., the fullerene-derivative materials such as C60 and PCBM, as well as the perovskite absorber, from water ingress and damage induced by the sputtering of the transparent front contact. Our study undertakes a comprehensive investigation of the impact of SnO 2 ALD processing on fullerenes by means of in situ spectroscopic ellipsometry (SE) and transmission infrared spectroscopy (FTIR). While no difference in SnO 2 bulk properties is observed and the perovskite absorber degradation is nearly entirely avoided during exposure to heat and vacuum, when the absorber is introduced beneath the organic ETLs, a SnO 2 growth delay of about 50 ALD cycles is measured on PCBM, whereas the delay is limited to 10 cycles in the case of growth on C60. Notably, FTIR measurements show that while C60 remains chemically unaffected during SnO 2 ALD growth, PCBM undergoes chemical modification, specifically of its ester groups. The onset of these modifications corresponds with the detection of the onset, after the initial delay, of ALD SnO 2 growth. It is expected that the modification that the PCBM layer undergoes upon ALD SnO 2 processing is responsible for the systematic lower photovoltaic device performance in the case of PCBM-based devices, with respect to C60-based devices.

Published

2024

31. In Situ IR Spectroscopy Studies of Atomic Layer-Deposited SnO 2 on Formamidinium-Based Lead Halide Perovskite.

Author

Bracesco AEA, Jansen JWP, Xue H, Zardetto V, Brocks G, Kessels WMM, Tao S, and Creatore M

Abstract

Perovskite photovoltaics has achieved conversion efficiencies of 26.0% by optimizing the optoelectronic properties of the absorber and its interfaces with charge transport layers (CTLs). However, commonly adopted organic CTLs can lead to parasitic absorption and device instability. Therefore, metal oxides like atomic layer-deposited (ALD) SnO 2 in combination with fullerene-based electron transport layers have been introduced to enhance mechanical and thermal stability. Instead, when ALD SnO 2 is directly processed on the absorber, i.e., without the fullerene layer, chemical modifications of the inorganic fraction of the perovskite occur, compromising the device performance. This study focuses on the organic fraction, particularly the formamidinium cation (FA + ), in a CsFAPb(I,Br) 3 perovskite. By employing in situ infrared spectroscopy, we investigate the impact of ALD processing on the perovskite, such as vacuum level, temperature, and exposure to half and full ALD cycles using tetrakis(dimethylamido)-Sn(IV) (TDMA-Sn) and H 2 O. We observe that exposing the absorber to vacuum conditions or water half-cycles has a negligible effect on the chemistry of the perovskite. However, prolonged exposure at 100 °C for 90 min results in a loss of 0.7% of the total formamidinium-related vibrational features compared to the pristine perovskite. Supported by density functional theory calculations, we speculate that FA + deprotonates and that formamidine desorbs from the perovskite surface. Furthermore, the interaction between TDMA-Sn and FA + induces more decomposition of the perovskite surface compared to vacuum, temperature, or H 2 O exposure. During the exposure to 10 ALD half-cycles of TDMA-Sn, 4% of the total FA + -related infrared features are lost compared to the pristine perovskite. Additionally, IR spectroscopy suggests the formation and trapping of sym -triazine, i.e., a decomposition product of FA + . These studies enable to decouple the effects occurring during direct ALD processing on the perovskite and highlight the crucial role of the Sn precursor in affecting the perovskite surface chemistry and compromising the device performance.

Published

2023