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

Author

Zhao, Y. (author), Datta, Kunal (author), Paggiaro, Giulia (author), Liu, Hanchen (author), Fardousi, Mohua (author), Santbergen, R. (author), Procel Moya, P.A. (author), Han, C. (author), Yang, G. (author), Weeber, A.W. (author), Zeman, M. (author), Mazzarella, L. (author), Isabella, O. (author), Zhao, Y. (author), Datta, Kunal (author), Paggiaro, Giulia (author), Liu, Hanchen (author), Fardousi, Mohua (author), Santbergen, R. (author), Procel Moya, P.A. (author), Han, C. (author), Yang, G. (author), Weeber, A.W. (author), Zeman, M. (author), Mazzarella, L. (author), and Isabella, O. (author)

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., Photovoltaic Materials and Devices

Published
2023
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7. Strategies for realizing high-efficiency silicon heterojunction solar cells

Author

Zhao, Y. (author), Procel Moya, P.A. (author), Han, C. (author), Cao, L. (author), Yang, G. (author), Özkol, E. (author), Alcañiz, Alba (author), Kovačević, K. (author), Limodio, G. (author), Santbergen, R. (author), Smets, A.H.M. (author), Weeber, A.W. (author), Zeman, M. (author), Mazzarella, L. (author), Isabella, O. (author), Zhao, Y. (author), Procel Moya, P.A. (author), Han, C. (author), Cao, L. (author), Yang, G. (author), Özkol, E. (author), Alcañiz, Alba (author), Kovačević, K. (author), Limodio, G. (author), Santbergen, R. (author), Smets, A.H.M. (author), Weeber, A.W. (author), Zeman, M. (author), Mazzarella, L. (author), and Isabella, O. (author)

Abstract

Silicon heterojunction (SHJ) solar cells have achieved a record efficiency of 26.81% in a front/back-contacted (FBC) configuration. Moreover, thanks to their advantageous high VOC and good infrared response, SHJ solar cells can be further combined with wide bandgap perovskite cells forming tandem devices to enable efficiencies well above 33%. In this study, we present strategies to realize high-efficiency SHJ solar cells through combined theoretical and experimental studies, starting from the optimization of Si-based thin-film layers to the implementation of electrodes with reduced indium and silver usage. Advanced opto-electrical simulations, which enable comprehensive theoretical understandings of the main physical mechanisms governing carriers’ collection and light management, provide clear pathways for device designs and experimental optimizations. We present the fabricated FBC-SHJ solar cells in both monofacial and bifacial configurations with the best efficiencies of 24.18% and 23.25%, respectively. We point out that to achieve optimum device performance, the compositional materials should be holistically optimized and evaluated as part of the contact stacks with adjacent layers. As an outlook beyond the classical FBC-SHJ solar cell architecture, we propose various novel SHJ-based solar cell architectures. Their potential performance was assessed and compared via rigorous opto-electrical simulations and a maximal efficiency of 27.60% was simulated for FBC-SHJ solar cells featuring localized contacts., Photovoltaic Materials and Devices, Electrical Engineering, Mathematics and Computer Science, QN/Kavli Nanolab Delft, Electrical Sustainable Energy

Published
2023
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8. Developing an energy rating for bifacial photovoltaic modules

Author

Vogt, M.R. (author), Pilis, Giorgos (author), Zeman, M. (author), Santbergen, R. (author), Isabella, O. (author), Vogt, M.R. (author), Pilis, Giorgos (author), Zeman, M. (author), Santbergen, R. (author), and Isabella, O. (author)

Abstract

The photovoltaic (PV) module energy rating standard series IEC 61853 does not cover bifacial PV modules. However, the market share of bifacial PV modules has dramatically increased in recent years and is projected to grow. This work demonstrates how Parts 3 and 4 of the IEC 61853 standard could be extended to bifacial modules. First, we develop an irradiance model that uses the data already given in the standard IEC 61853-4 to calculate the irradiance on the rear side of the module. Second, we propose a way to extend the energy yield calculation algorithm IEC 61853-3 to include bifacial modules and make it available to the PV community. This rear irradiance and bifacial energy yield calculation procedure is tested using real outdoor measurements for a nine-month period with a root mean square difference between measured and simulated energy yield of 4.65%. To conclude, we investigate the impact of different climates and normalization on the bifacial module energy rating results., Photovoltaic Materials and Devices, Electrical Sustainable Energy

Published
2023
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9. Energy Loss Analysis of Two-Terminal Tandem PV Systems under Realistic Operating Conditions—Revealing the Importance of Fill Factor Gains

Author

Blom, Y. (author), Vogt, M.R. (author), Ruiz Tobon, C.M. (author), Santbergen, R. (author), Zeman, M. (author), Isabella, O. (author), Blom, Y. (author), Vogt, M.R. (author), Ruiz Tobon, C.M. (author), Santbergen, R. (author), Zeman, M. (author), and Isabella, O. (author)

Abstract

The tandem PV technology can potentially increase the efficiency of PV modules over 30%. To design efficient modules, a quantification of the different losses is important. Herein, a model for quantifying the energy loss mechanisms in PV systems under real-world operating conditions with a level of detail back to the components and their fundamental properties is presented. Totally, 17 losses are defined and divided into four categories (fundamental, optical, electrical, and system losses). As example, a system based on a > 29% two-terminal perovskite/silicon tandem cell is considered. The loss distribution at standard test conditions is compared to four geographical locations. The results show that the thermalization, reflection, and inverter losses increase by 1.2%, 1.1%, and 1.4%, respectively, when operating outdoors. Additionally, it is quantified how fill factor gains partly compensate the current mismatch losses. For example, a mismatch of 7.0% in photocurrent leads to a power mismatch of 1.2%. Therefore, the power mismatch should be used as indicator for mismatch losses instead of a current mismatch. Finally, herein, it is shown that solar tracking increases not only the in-plane irradiance but also the efficiency of the tandem module., Photovoltaic Materials and Devices, Electrical Sustainable Energy

Published
2023
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13. Slow Shallow Energy States as the Origin of Hysteresis in Perovskite Solar Cells

Author

van Heerden, Rik (author), Procel Moya, P.A. (author), Mazzarella, L. (author), Santbergen, R. (author), Isabella, O. (author), van Heerden, Rik (author), Procel Moya, P.A. (author), Mazzarella, L. (author), Santbergen, R. (author), and Isabella, O. (author)

Abstract

Organic-inorganic metal halide perovskites have attracted a considerable interest in the photovoltaic scientific community demonstrating a rapid and unprecedented increase in conversion efficiency in the last decade. Besides the stunning progress in performance, the understanding of the physical mechanisms and limitations that govern perovskite solar cells are far to be completely unravelled. In this work, we study the origin of their hysteretic behaviour from the standpoint of fundamental semiconductor physics by means of technology computer aided design electrical simulations. Our findings identify that the density of shallow interface defects at the interfaces between perovskite and transport layers plays a key role in hysteresis phenomena. Then, by comparing the defect distributions in both spatial and energetic domains for different bias conditions and using fundamental semiconductor equations, we can identify the driving force of hysteresis in terms of slow recombination processes and charge distributions., Photovoltaic Materials and Devices

Published
2022
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14. Ray-optics study of gentle non-conformal texture morphologies for perovskite/silicon tandems

Author

Santbergen, R. (author), Vogt, M.R. (author), Mishima, Ryota (author), Hino, Masashi (author), Uzu, Hisashi (author), Adachi, Daisuke (author), Yamamoto, Kenji (author), Zeman, M. (author), Isabella, O. (author), Santbergen, R. (author), Vogt, M.R. (author), Mishima, Ryota (author), Hino, Masashi (author), Uzu, Hisashi (author), Adachi, Daisuke (author), Yamamoto, Kenji (author), Zeman, M. (author), and Isabella, O. (author)

Abstract

We investigate gentle front side textures for perovskite/silicon tandem solar cells. These textures enhance the absorption of sunlight, yet are sufficiently gentle to allow deposition of an efficient perovskite top cell. We present a tandem solar cell with such gentle texture, fabricated by Kaneka corporation, with an efficiency as high as 28.6%. We perform an extensive ray-optics study, exploring non-conformal textures at the front and rear side of the perovskite layer. Our results reveal that a gentle texture with steepness of only 23° can be more optically efficient than conventional textures with more than double that steepness. We also show that the observed anti-reflective effect of such gentle textures is not based a double bounce, but on light trapping by total internal reflection. As a result, the optical effects of the encapsulation layers play an important role, and have to be accounted for when evaluating the texture design for perovskite/silicon tandems., Photovoltaic Materials and Devices, Electrical Sustainable Energy

Published
2022
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15. Three-terminal perovskite/integrated back contact silicon tandem solar cells under low light intensity conditions

Author

Kanda, Hiroyuki (author), Dan Mihailetchi, Valentin (author), Gueunier‐Farret, Marie‐Estelle (author), Kleider, Jean‐Paul (author), Djebbour, Zakaria (author), Alvarez, Jose (author), Isabella, O. (author), Vogt, M.R. (author), Santbergen, R. (author), Kanda, Hiroyuki (author), Dan Mihailetchi, Valentin (author), Gueunier‐Farret, Marie‐Estelle (author), Kleider, Jean‐Paul (author), Djebbour, Zakaria (author), Alvarez, Jose (author), Isabella, O. (author), Vogt, M.R. (author), and Santbergen, R. (author)

Abstract

The current climate and energy crisis urgently needs solar cells with efficiencies above the 29% single junction efficiency bottleneck. Silicon/perovskite tandem solar cells are a solution, which is attracting much attention. While silicon/perovskite tandem cells in 2-terminal and 4-terminal configurations are well documented, the three-terminal concept is still in its infancy. It has significant advantages under low light intensities as opposed to concentrated sunlight, which is the critical factor in designing tandem solar cells for low-cost terrestrial applications. This study presents novel studies of the sub-cell performance of the first three-terminal perovskite/silicon selective band offset barrier tandem solar cells fabricated in an ongoing research project. This study focuses on short circuit current and operating voltages of the sub-cells under light intensities of one sun and below. Lifetime studies show that the perovskite bulk carrier lifetime is insensitive to illumination, while the silicon cell's lifetime decreases with decreasing light intensity. The combination of perovskite and silicon in the 3T perovskite-silicon tandem therefore reduces the sensitivity of VOC to light intensity and maintains a relatively higher VOC down to low light intensities, whereas silicon single-junction cells show a marked decrease. This technological advantage is proposed as a novel advantage of three-terminal perovkite/silicon solar cells for low light intensities of one sun or less., Photovoltaic Materials and Devices

Published
2022
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16. Concepts for heat utilization and passive cooling techniques to improve reliability and performance of Building Integrated Photovoltaics (BIPV)

Author

Ortiz Lizcano, J.C. (author), Calcabrini, A. (author), Santbergen, R. (author), Procel Moya, P.A. (author), Zeman, M. (author), Isabella, O. (author), Ortiz Lizcano, J.C. (author), Calcabrini, A. (author), Santbergen, R. (author), Procel Moya, P.A. (author), Zeman, M. (author), and Isabella, O. (author)

Abstract

When integrated into urban environments, photovoltaic (PV) systems usually present operational temperatures that are significantly higher than those shown by rack-mounted systems. High operating temperatures are associated with reduced reliability of PV modules and significantly impact the electrical performance of solar cells. Utilizing the heat produced on PV modules or reducing operating temperatures can bolster their application within the building sector. We present the three main concepts studied to achieve these goals. First, a PV is a chimney concept that allows the use of the heat generated by the modules. Simulations for a PV chimney installed on a building in the Netherlands showed that although the heat quality produced inside its cavity was low, the potential use of the air mass flow for ventilation applications is promising. Additionally, we present two passive cooling solutions that can reduce the operating temperatures of PV modules: Optical filters and phase change materials. Experimental measurements in Delft showed that these solutions reduce the operating temperature of PV modules between 4 °C to 20 °C, particularly under high irradiance hours., Photovoltaic Materials and Devices, Electrical Sustainable Energy

Published
2022
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17. Achieving 23.83% conversion efficiency in silicon heterojunction solar cell with ultra-thin MoOx hole collector layer via tailoring (i)a-Si:H/MoOx interface

Author

Cao, L. (author), Procel Moya, P.A. (author), Alcañiz Moya, A. (author), Yan, J. (author), Tichelaar, F.D. (author), Özkol, E. (author), Zhao, Y. (author), Han, C. (author), Yang, G. (author), Yao, Z. (author), Zeman, M. (author), Santbergen, R. (author), Mazzarella, L. (author), Isabella, O. (author), Cao, L. (author), Procel Moya, P.A. (author), Alcañiz Moya, A. (author), Yan, J. (author), Tichelaar, F.D. (author), Özkol, E. (author), Zhao, Y. (author), Han, C. (author), Yang, G. (author), Yao, Z. (author), Zeman, M. (author), Santbergen, R. (author), Mazzarella, L. (author), and Isabella, O. (author)

Abstract

Thin films of transition metal oxides such as molybdenum oxide (MoOx) are attractive for application in silicon heterojunction solar cells for their potential to yield large short-circuit current density. However, full control of electrical properties of thin MoOx layers must be mastered to obtain an efficient hole collector. Here, we show that the key to control the MoOx layer quality is the interface between the MoOx and the hydrogenated intrinsic amorphous silicon passivation layer underneath. By means of ab initio modelling, we demonstrate a dipole at such interface and study its minimization in terms of work function variation to enable high performance hole transport. We apply this knowledge to experimentally tailor the oxygen content in MoOx by plasma treatments (PTs). PTs act as a barrier to oxygen diffusion/reaction and result in optimal electrical properties of the MoOx hole collector. With this approach, we can thin down the MoOx thickness to 1.7 nm and demonstrate short-circuit current density well above 40 mA/cm2 and a champion device exhibiting 23.83% conversion efficiency., Photovoltaic Materials and Devices, QN/Afdelingsbureau, Electrical Sustainable Energy

Published
2022
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18. Introducing a comprehensive physics-based modelling framework for tandem and other PV systems

Author

Vogt, M.R. (author), Ruiz Tobon, C.M. (author), Alcañiz Moya, A. (author), Procel Moya, P.A. (author), Blom, Y. (author), Nour El Din, A. (author), Stark, T. (author), Wang, Z. (author), Goma, E. Garcia (author), Etxebarria, J. G. (author), Ziar, H. (author), Zeman, M. (author), Santbergen, R. (author), Isabella, O. (author), Vogt, M.R. (author), Ruiz Tobon, C.M. (author), Alcañiz Moya, A. (author), Procel Moya, P.A. (author), Blom, Y. (author), Nour El Din, A. (author), Stark, T. (author), Wang, Z. (author), Goma, E. Garcia (author), Etxebarria, J. G. (author), Ziar, H. (author), Zeman, M. (author), Santbergen, R. (author), and Isabella, O. (author)

Abstract

We introduce a novel simulation tool capable of calculating the energy yield of a PV system based on its fundamental material properties and using self-consistent models. Thus, our simulation model can operate without measurements of a PV device. It combines wave and ray optics and a dedicated semiconductor simulation to model the optoelectronic PV device properties resulting in the IV-curve. The system surroundings are described via spectrally resolved ray tracing resulting in a cell resolved irradiance distribution, and via the fluid dynamics-based thermal model, in the individual cell temperatures. A lumped-element model is used to calculate the IV-curves of each solar cell for every hour of the year. These are combined factoring in the interconnection to obtain the PV module IV-curves, which connect to the inverter for calculating the AC energy yield. In our case study, we compare two types of 2 terminal perovskite/silicon tandem modules with STC PV module efficiencies of 27.7% and 28.6% with a reference c-Si module with STC PV module efficiency of 20.9%. In four different climates, we show that tandem PV modules operate at 1–1.9 °C lower yearly irradiance weighted average temperatures compared to c-Si. We find that the effect of current mismatch is significantly overestimated in pure optical studies, as they do not account for fill factor gains. The specific yields in kWh/kWp of the tandem PV systems are between −2.7% and +0.4% compared to the reference c-Si system in all four simulated climates. Thus, we find that the lab performance of the simulated tandem PV system translates from the laboratory to outdoors comparable to c-Si systems., Photovoltaic Materials and Devices, Energie and Industrie, Electrical Sustainable Energy

Published
2022
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20. Concepts for heat utilization and passive cooling techniques to improve reliability and performance of Building Integrated Photovoltaics (BIPV)

Author

Ortiz Lizcano, J.C., Calcabrini, A., Santbergen, R., Procel Moya, P.A., Zeman, M., and Isabella, O.

Subjects
General Medicine, General Chemistry
Abstract

When integrated into urban environments, photovoltaic (PV) systems usually present operational temperatures that are significantly higher than those shown by rack-mounted systems. High operating temperatures are associated with reduced reliability of PV modules and significantly impact the electrical performance of solar cells. Utilizing the heat produced on PV modules or reducing operating temperatures can bolster their application within the building sector. We present the three main concepts studied to achieve these goals. First, a PV is a chimney concept that allows the use of the heat generated by the modules. Simulations for a PV chimney installed on a building in the Netherlands showed that although the heat quality produced inside its cavity was low, the potential use of the air mass flow for ventilation applications is promising. Additionally, we present two passive cooling solutions that can reduce the operating temperatures of PV modules: Optical filters and phase change materials. Experimental measurements in Delft showed that these solutions reduce the operating temperature of PV modules between 4 °C to 20 °C, particularly under high irradiance hours.

Published
2022

23. Colored optic filters on c-Si IBC solar cells for building integrated photovoltaic applications

Author

Ortiz Lizcano, J.C. (author), Procel Moya, P.A. (author), Calcabrini, A. (author), Yang, G. (author), Ingenito, Andrea (author), Santbergen, R. (author), Zeman, M. (author), Isabella, O. (author), Ortiz Lizcano, J.C. (author), Procel Moya, P.A. (author), Calcabrini, A. (author), Yang, G. (author), Ingenito, Andrea (author), Santbergen, R. (author), Zeman, M. (author), and Isabella, O. (author)

Abstract

Building Integrated Photovoltaic systems can produce a significant portion of the energy demand of urban areas. Despite their potential, they remain a niche technology that architects and project engineers still find esthetically limited. The dark blue or black color of standard photovoltaic panels is considered inappropriate for restoration projects of historic buildings and represents a major constraint on the development of new projects. This work will provide insight into how the use of optic filters can offer new pathways for architectural acceptance of photovoltaic panels. Optic filters selectively reflect or transmit light by interference and can be designed and fabricated using cost-effective and industrially compatible processes. By using in-house developed ray tracing software coupled with TCAD Sentaurus, more than 400 colors were obtained, and their impact on the opto-electrical performance of interdigitated back-contacted solar cells was studied. Results show a maximum efficiency loss of 1.6% absolute at the perpendicular incidence of light on the range of obtained colors when compared with a standard dark blue solar cell. Simulations for different angles of incidence showed that the current reduction on the standard device could be modeled using a cosine relationship. The colored cells, however, deviated significantly from this relationship. We propose that the angular behavior of any cell (colored or standard) could be simulated by modifying the effective irradiance with scaling factors equal to the ratios of the photogenerated current at any angle with respect to the value at normal incidence. We demonstrate that this approach accurately models the effect of the color filter and allows for an easy transition from a bare cell to an encapsulated one. Due to the spectral effect of the filter, we developed both a spectrally resolved optical model and a two-dimensional finite volume transient thermal model. In case of the optical model, we demonstrate a, Photovoltaic Materials and Devices, Electrical Sustainable Energy

Published
2021
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24. A silicon carbide-based highly transparent passivating contact for crystalline silicon solar cells approaching efficiencies of 24%

Author

Köhler, Malte (author), Pomaska, Manuel (author), Procel Moya, P.A. (author), Santbergen, R. (author), Lambertz, Andreas (author), Duan, Weiyuan (author), Eberst, Alexander (author), Luysberg, Martina (author), Isabella, O. (author), Köhler, Malte (author), Pomaska, Manuel (author), Procel Moya, P.A. (author), Santbergen, R. (author), Lambertz, Andreas (author), Duan, Weiyuan (author), Eberst, Alexander (author), Luysberg, Martina (author), and Isabella, O. (author)

Abstract

A highly transparent passivating contact (TPC) as front contact for crystalline silicon (c-Si) solar cells could in principle combine high conductivity, excellent surface passivation and high optical transparency. However, the simultaneous optimization of these features remains challenging. Here, we present a TPC consisting of a silicon-oxide tunnel layer followed by two layers of hydrogenated nanocrystalline silicon carbide (nc-SiC:H(n)) deposited at different temperatures and a sputtered indium tin oxide (ITO) layer (c-Si(n)/SiO2/nc-SiC:H(n)/ITO). While the wide band gap of nc-SiC:H(n) ensures high optical transparency, the double layer design enables good passivation and high conductivity translating into an improved short-circuit current density (40.87 mA cm−2), fill factor (80.9%) and efficiency of 23.99 ± 0.29% (certified). Additionally, this contact avoids the need for additional hydrogenation or high-temperature postdeposition annealing steps. We investigate the passivation mechanism and working principle of the TPC and provide a loss analysis based on numerical simulations outlining pathways towards conversion efficiencies of 26%., Electrical Sustainable Energy, Photovoltaic Materials and Devices

Published
2021
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25. Room-temperature sputtered tungsten-doped indium oxide for improved current in silicon heterojunction solar cells

Author

Han, C. (author), Zhao, Y. (author), Mazzarella, L. (author), Santbergen, R. (author), Bento Montes, A.R. (author), Procel Moya, P.A. (author), Yang, G. (author), Zhang, Xiaodan (author), Zeman, M. (author), Isabella, O. (author), Han, C. (author), Zhao, Y. (author), Mazzarella, L. (author), Santbergen, R. (author), Bento Montes, A.R. (author), Procel Moya, P.A. (author), Yang, G. (author), Zhang, Xiaodan (author), Zeman, M. (author), and Isabella, O. (author)

Abstract

The window layers limit the performance of silicon heterojunction (SHJ) solar cells with front and back contacts. Here, we optimized tungsten-doped indium oxide (IWO) film deposited by radio frequency magnetron sputtering at room temperature. The opto-electrical properties of the IWO were manipulated when deposited on top of thin-film silicon layers. The optimal IWO on glass shows carrier density and mobility of 2.1 × 1020 cm−3 and 34 cm2 V−1s−1, respectively, which were tuned to 2.0 × 1020 cm−3 and 47 cm2 V−1s−1, as well as 1.9 × 1020 cm−3 and 42 cm2 V−1s−1, after treated on i/n/glass and i/p/glass substrates, respectively. Using the more realistic TCO data that were obtained on thin-film silicon stacks, optical simulation indicates a promising visible-to-near-infrared optical response in IWO-based SHJ device structure, which was demonstrated in fabricated devices. Additionally, by adding an additional magnesium fluoride layer on device, the champion IWO-based SHJ device showed an active area cell efficiency of 22.92%, which is an absolute 0.98% efficiency gain compared to the ITO counterpart, mainly due to its current gain of 1.48 mA/cm2., Photovoltaic Materials and Devices, Electrical Sustainable Energy

Published
2021
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26. Comparing optical performance of a wide range of perovskite/silicon tandem architectures under real-world conditions

Author

Singh, M. (author), Santbergen, R. (author), Syifai, Indra (author), Zeman, M. (author), Isabella, O. (author), Singh, M. (author), Santbergen, R. (author), Syifai, Indra (author), Zeman, M. (author), and Isabella, O. (author)

Abstract

Since single junction c-Si solar cells are reaching their practical efficiency limit. Perovskite/c-Si tandem solar cells hold the promise of achieving greater than 30% efficiencies. In this regard, optical simulations can deliver guidelines for reducing the parasitic absorption losses and increasing the photocurrent density of the tandem solar cells. In this work, an optical study of 2, 3 and 4 terminal perovskite/c-Si tandem solar cells with c-Si solar bottom cells passivated by high thermal-budget poly-Si, poly-SiOx and poly-SiCx is performed to evaluate their optical performance with respect to the conventional tandem solar cells employing silicon heterojunction bottom cells. The parasitic absorption in these carrier selective passivating contacts has been quantified. It is shown that they enable greater than 20 mA/cm2 matched implied photocurrent density in un-encapsulated 2T tandem architecture along with being compatible with high temperature production processes. For studying the performance of such tandem devices in real-world irradiance conditions and for different locations of the world, the effect of solar spectrum and angle of incidence on their optical performance is studied. Passing from mono-facial to bi-facial tandem solar cells, the photocurrent density in the bottom cell can be increased, requiring again optical optimization. Here, we analyse the effect of albedo, perovskite thickness and band gap as well as geographical location on the optical performance of these bi-facial perovskite/c-Si tandem solar cells. Our optical study shows that bi-facial 2T tandems, that also convert light incident from the rear, require radically thicker perovskite layers to match the additional current from the c-Si bottom cell. For typical perovskite bandgap and albedo values, even doubling the perovskite thickness is not sufficient. In this respect, lower bandgap perovskites are very interesting for application not only in bi-facia, Photovoltaic Materials and Devices, Electrical Sustainable Energy

Published
2021
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27. Multiscale design of perovskite on silicon band offset barrier tandem solar cells

Author

Connolly, J.P. (author), Alvarez , J (author), Ahanogbe, Koffi (author), Kleider, Jean‐Paul (author), Kanda, Hiroyuki (author), Khaja Nazeeruddin, Mohammad (author), Vogt, M.R. (author), Santbergen, R. (author), Isabella, O. (author), Connolly, J.P. (author), Alvarez , J (author), Ahanogbe, Koffi (author), Kleider, Jean‐Paul (author), Kanda, Hiroyuki (author), Khaja Nazeeruddin, Mohammad (author), Vogt, M.R. (author), Santbergen, R. (author), and Isabella, O. (author)

Abstract

Photovoltaic Materials and Devices

Published
2021

28. Realistic limits of perovskite solar cell efficiency

Author

Connolly, J.P. (author), Alvarez , J (author), Ahanogbe, Koffi (author), Kleider, Jean‐Paul (author), Djebbour, Zakaria (author), Kanda, Hiroyuki (author), Vogt, M.R. (author), Santbergen, R. (author), Isabella, O. (author), Connolly, J.P. (author), Alvarez , J (author), Ahanogbe, Koffi (author), Kleider, Jean‐Paul (author), Djebbour, Zakaria (author), Kanda, Hiroyuki (author), Vogt, M.R. (author), Santbergen, R. (author), and Isabella, O. (author)

Abstract

The perovskite solar cell (PSC) is one of the most dramatic inventions in the field of photovoltaics in the last half century. The device has rapidly risen from a few percent to efficiencies of over 24% [1] in little over a decade. This rapid development is due in part to the wide family of perovskite absorber and of electron and hole tranport materials available which yields great flexibility. The flip-side of this profusion of materials is the challenge in establishing achievable performance potential of real devices. This paper therefore presents a study of the perovskite solar cell materials and applies numerical modelling techniques to evaluate the most promising materials combinations and their efficiency potential. The preliminary device structure is a simple three-layer design consisting of hole transport layer, perovskite aborber, and electron transport layer, on a glass substrate in a p-i-n or “inverted” configuration. A range of materials for these layers is compared and contrasted for this polarity. The structure is then generalised to more complex designs featuring protective buffer layers which prevent damage to the perovskite absorber layer, and two dimensional perovkite layers which have been shown to improve perovskite material stability. The realistic efficiency potential of the materials considered is discused in the context of the common radiative efficiency limit. The study concludes by recommending promising materials combinations for high efficiency PSC compatible with cost effective indutrial fabrication method for single juntion and for multijunction device design in the context of H2020 Solar-ERANET project BOBTANDEM [2]. This work contributes to define efficiencies achievable in this materials systems, both for single junction and multijunction devices which are of great societal interet for cost effective renewable power generation., Photovoltaic Materials and Devices

Published
2021

30. Recent results on carrier selective three terminal perovskite on silicon-IBC tandem solar cells

Author

Connolly, J. P., koffi Fafadji AHANOGBE, Kleider, Jean-Paul P., Alvarez, J., Hiroyuki Kanda, Nazeeruddin, M. K., Valentin Mihailetchi, Philippe Baranek, Malte Vogt, Santbergen, R., Olindo Isabella, Connolly, James, Laboratoire Génie électrique et électronique de Paris (GeePs), CentraleSupélec-Sorbonne Université (SU)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), Group for Molecular Engineering of Functional Materials, Institut des Sciences et Ingénierie Chimiques (ISIC), Ecole Polytechnique Fédérale de Lausanne (EPFL)-Ecole Polytechnique Fédérale de Lausanne (EPFL), International Solar Energy Research Center (ISE Konstanz e.V.), Economie, Fonctionnement et Etudes des Systèmes Électriques (EDF R&D EFESE), EDF R&D (EDF R&D), EDF (EDF)-EDF (EDF), Institut Photovoltaïque d’Ile-de-France (ITE) (IPVF), and Delft University of Technology (TU Delft)

Subjects
Silicon, [SPI.OPTI] Engineering Sciences [physics]/Optics / Photonic, Multijunction, Novel device, [SPI.NANO] Engineering Sciences [physics]/Micro and nanotechnologies/Microelectronics, [SPI.NRJ]Engineering Sciences [physics]/Electric power, [SPI.MAT] Engineering Sciences [physics]/Materials, Perovskite, [PHYS.COND.CM-MS] Physics [physics]/Condensed Matter [cond-mat]/Materials Science [cond-mat.mtrl-sci], [SPI.MAT]Engineering Sciences [physics]/Materials, [PHYS.COND.CM-MS]Physics [physics]/Condensed Matter [cond-mat]/Materials Science [cond-mat.mtrl-sci], [SPI.OPTI]Engineering Sciences [physics]/Optics / Photonic, [SPI.NANO]Engineering Sciences [physics]/Micro and nanotechnologies/Microelectronics, High efficiency, [SPI.NRJ] Engineering Sciences [physics]/Electric power
Abstract

International audience; The most successful high efficiency design, and one of the oldest, is the multi-junction solar cell. There are a range of multijunction solar cell terminal configurations, the specificities of which are reviewed, concluding with noting the increased attention being given to three terminal designs. This introduces a new device design which is the Three Terminal Selective Band Offset Barrier tandem solar cell. The physical operation of this new device is examined, and embodiments in prototype materials relying on materials properties from the literature. We present projected performance evaluated by two dimensional numerical modelling. Identifying shortcomings on two fronts of materials and optical properties of the multilayer stack, we describe theoretical progress in optimising these properties via ab initio materials modelling and combined ray and wave optics. This theoretical context introduces the experimental results obtained in the first year of the project. This consists of successful integration of the selective band offset barrier on a suitably modified IBC structure using prototype materials previously reported. This paper thereby presents detailed analysis of the three terminal selective band offset barrier tandem solar cell, and announces the first experimentally fabricated three terminal selective band offset barrier solar cells, together with preliminary conclusions of experimental characterisation which is underway. .

Published
2020

31. Recent results on carrier selective three terminal perovskite on silicon-IBC tandem solar cells

Author

Connolly, J.P., Ahanogbe, Koffi, Kleider, Jean‐Paul, Alvarez, J, Kanda, Hiroyuki, Khaja Nazeeruddin, Mohammad, Vogt, M.R., Santbergen, R., and Isabella, O.

Abstract

The most successful high efficiency design, and one of the oldest, is the multi-junction solar cell. There are a range of multijunction solar cell terminal configurations, the specificities of which are reviewed, concluding with noting the increased attention being given to three terminal designs. This introduces a new device design which is the Three Terminal Selective Band Offset Barrier tandem solar cell. The physical operation of this new device is examined, and embodiments in prototype materials relying on materials properties from the literature. We present projected performance evaluated by two dimensional numerical modelling. Identifying shortcomings on two fronts of materials and optical properties of the multilayer stack, we describe theoretical progress in optimising these properties via ab initio materials modelling and combined ray and wave optics. This theoretical context introduces the experimental results obtained in the first year of the project. This consists of successful integration of the selective band offset barrier on a suitably modified IBC structure using prototype materials previously reported. This paper thereby presents detailed analysis of the three terminal selective band offset barrier tandem solar cell, and announces the first experimentally fabricated three terminal selective band offset barrier solar cells, together with preliminary conclusions of experimental characterisation which is underway. .

Published
2020

32. Innovative floating bifacial photovoltaic solutions for inland water areas

Author

Ziar, H. (author), Prudon, Bjorn (author), Lin, Fen Yu (author), Stark, Tim (author), Teurlincx, Sven (author), Goma, Elias Garcia (author), Alavez, Ignacio Narvaez (author), Santbergen, R. (author), Isabella, O. (author), Ziar, H. (author), Prudon, Bjorn (author), Lin, Fen Yu (author), Stark, Tim (author), Teurlincx, Sven (author), Goma, Elias Garcia (author), Alavez, Ignacio Narvaez (author), Santbergen, R. (author), and Isabella, O. (author)

Abstract

Photovoltaic (PV) technology has the potential to be integrated on many surfaces in various environments, even on water. Modeling, design, and realization of a floating PV system have more challenges than conventional rooftop or freestanding PV system. In this work, we introduce two innovative concepts for floating bifacial PV systems, describing their modeling, design, and performance monitoring. The developed concepts are retractable and enable maximum energy production through tracking the Sun. Various floating PV systems (monofacial, bifacial with and without reflectors) with different tilts and tracking capabilities are installed on a Dutch pond and are being monitored. Results of the thermal study showed that partially soaking the frame of PV modules into water does not bring a considerable additional yield (+0.17%) and revealed that floating PV modules experience higher temperature special variance compared with land-based systems. Observations showed that the birds' presence has a severe effect on floating PV performance in the short term. Electrical yield investigation concluded that due to low albedo of inland water areas (~6.5%), bifacial PV systems must have reflectors. One-year monitoring showed that a bifacial PV system with reflector and horizontal tracking delivers ~17.3% more specific yield (up to 29% in a clear-sky month) compared with a monofacial PV system installed on land. Ecological monitoring showed no discernable impacts on the water quality in weekly samplings but did show significant impacts on the aquatic plant biomass and periods of low oxygen concentrations., Photovoltaic Materials and Devices

Published
2020
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33. Recent results on carrier selective three terminal perovskite on silicon-IBC tandem solar cells

Author

Connolly, J.P. (author), Ahanogbe, Koffi (author), Kleider, Jean‐Paul (author), Alvarez , J (author), Kanda, Hiroyuki (author), Khaja Nazeeruddin, Mohammad (author), Vogt, M.R. (author), Santbergen, R. (author), Isabella, O. (author), Connolly, J.P. (author), Ahanogbe, Koffi (author), Kleider, Jean‐Paul (author), Alvarez , J (author), Kanda, Hiroyuki (author), Khaja Nazeeruddin, Mohammad (author), Vogt, M.R. (author), Santbergen, R. (author), and Isabella, O. (author)

Abstract

The most successful high efficiency design, and one of the oldest, is the multi-junction solar cell. There are a range of multijunction solar cell terminal configurations, the specificities of which are reviewed, concluding with noting the increased attention being given to three terminal designs. This introduces a new device design which is the Three Terminal Selective Band Offset Barrier tandem solar cell. The physical operation of this new device is examined, and embodiments in prototype materials relying on materials properties from the literature. We present projected performance evaluated by two dimensional numerical modelling. Identifying shortcomings on two fronts of materials and optical properties of the multilayer stack, we describe theoretical progress in optimising these properties via ab initio materials modelling and combined ray and wave optics. This theoretical context introduces the experimental results obtained in the first year of the project. This consists of successful integration of the selective band offset barrier on a suitably modified IBC structure using prototype materials previously reported. This paper thereby presents detailed analysis of the three terminal selective band offset barrier tandem solar cell, and announces the first experimentally fabricated three terminal selective band offset barrier solar cells, together with preliminary conclusions of experimental characterisation which is underway. ., Photovoltaic Materials and Devices

Published
2020

34. Optical characterization of poly-SiOx and poly-SiCx carrier-selective passivating contacts

Author

Singh, M. (author), Santbergen, R. (author), Mazzarella, L. (author), Madrampazakis, A. (author), Yang, G. (author), Vismara, R. (author), Remes, Z. (author), Weeber, A.W. (author), Zeman, M. (author), Isabella, O. (author), Singh, M. (author), Santbergen, R. (author), Mazzarella, L. (author), Madrampazakis, A. (author), Yang, G. (author), Vismara, R. (author), Remes, Z. (author), Weeber, A.W. (author), Zeman, M. (author), and Isabella, O. (author)

Abstract

The optical modelling for optimizing high-efficiency c-Si solar cells endowed with poly-SiOx or poly-SiCx carrier-selective passivating contacts (CSPCs) demands a thorough understanding of their optical properties, especially their absorption coefficient. Due to the mixed phase nature of these CSPCs, spectroscopic ellipsometry is unable to accurately detect the weak free carrier absorption (FCA) at long wavelengths. In this work, the absorption coefficient of doped poly-SiOx and poly-SiCx layers as function of oxygen and carbon content, respectively, was obtained for wavelengths (300–2000 nm) by means of two alternative techniques. The first approach, photothermal deflection spectroscopy (PDS), was used for layers grown on quartz substrates and is appealing from the point of view of sample fabrication. The second, a novel inverse modelling (IM) approach based on reflectance and transmittance measurements, was instead used for layers grown on textured c-Si wafer substrates to mimic symmetrical samples. Although the absorption coefficients obtained from these two techniques slightly differ due to the different used substrates, we could successfully measure weak FCA in our CSPCs layers. Using an in-house developed multi-optical regime simulator and comparing modelled reflectance and transmittance with measured counterparts from symmetrical samples, we confirmed that with increasing doping concentration FCA increases; and found that the absorption coefficients obtained from IM can now be used to perform optical simulations of these CSPCs in solar cells., Photovoltaic Materials and Devices, Electrical Sustainable Energy

Published
2020
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36. Optimization of Three-Terminal Perovskite/Silicon Tandem Solar Cells

Author

Santbergen, R. (author), Uzu, Hisashi (author), Yamamoto, Kenji (author), Zeman, M. (author), Santbergen, R. (author), Uzu, Hisashi (author), Yamamoto, Kenji (author), and Zeman, M. (author)

Abstract

We use simulations to optimize perovskite/silicon tandem solar cells in a novel three-terminal configuration, with one terminal at the front and two at the rear. We consider configurations in which the top cell has either the inverted or the same polarity as the bottom cell. Our goal is to minimize the optical losses, to compare the performance of both configurations and to determine the realistically achievable efficiency. Optical simulations show that if the hole-transporting material is in front of the perovskite, it gives rise to parasitic absorption losses. If it is behind the perovskite, these losses are avoided, however, at the cost of increased reflection losses. We systematically minimize these reflection losses. This increases the tandem's total implied photocurrent density from 34.4 to 41.1 mA/cm 2 . To determine the corresponding power conversion efficiency of these three-terminal tandems, electrical circuit simulations are performed based on existing 22.7% efficient perovskite and 24.9% efficient silicon cells. These simulations show that tandem efficiencies up to 32.0% can be obtained., Accepted author manuscript, Photovoltaic Materials and Devices, Electrical Sustainable Energy

Published
2019
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38. Finding the most suitable PV technology for a ZigZag-structured PV facade in NW-Europe

Author

Valckenborg, R.M.E., Sasidharan, S., Tzikas, C., Santbergen, R., Van De Wall, W., and Folkerts, W.

Subjects
PV Systems - Performance, Applications and Integration, Building, Infrastructure, Landscape and Other Applications of PV, Design, Energy, Façade, NZEB, PV System, Energy Efficiency, Energy Performance, Energy / Geological Survey Netherlands, BIPV, Solar Radiation, CIGS
Abstract

35th European Photovoltaic Solar Energy Conference and Exhibition; 1821-1827, Choosing the most suitable PV technology for a ZigZag-structured façade cannot be based on one aspect, but involves four important aspects. First, a maximal energy density (Wp/m2 panel) of the PV-panel itself is preferred. Secondly, the amount of irradiance from the reflective panels onto the PV-panels should be maximized. However that could lead to a non-uniform irradiance distribution because of self-shading. The development of a custom made irradiance model has turned out to be crucial to predict full year irradiance and energy yield. This model is validated with an experimental setup for three different angles of reflective panels. In this setup, not only irradiance is measured, but also electrical (specific) yield Y [kWh/kWp]. The graphical representation of Y and PR in the IEC 61853-matrix reveals clearly how local climate conditions have an influence on the full year result. Thirdly, the resulting yearly specific yield [kWh/kWp/yr] is depending on the way that the PV-panel can deal with the non-uniformities. Finally, by introducing a new parameter called ‘effective façade PV-coverage’ [kWp/m2 façade] the results of specific yield can be modeled, measured and presented in ‘effective façade yield’ [kWh/m2 façade]. This parameter is directly of use for project developers, architects, contractors and other stakeholders in the building industry. The full methodology of this paper could in principle be applied not only to ZigZag-structured façades, but also to other complex PV-building skins with any orientation at any location in the world.

Published
2018

39. Maximizing annual yield of bifacial photovoltaic noise barriers

Author

Faturrochman, G.J. (author), de Jong, M.M. (author), Santbergen, R. (author), Folkerts, W. (author), Zeman, M. (author), Smets, A.H.M. (author), Faturrochman, G.J. (author), de Jong, M.M. (author), Santbergen, R. (author), Folkerts, W. (author), Zeman, M. (author), and Smets, A.H.M. (author)

Abstract

In this work we consider noise barriers with integrated photovoltaic modules. The novelty is that bifacial modules are considered. A full scale bifacial photovoltaic noise barrier was built and its power output was monitored. In addition we developed an advanced numerical model for predicting this power output for given weather conditions. Excellent agreement was found between the measured power output and the model prediction. Next we used this model to demonstrate the effects of the orientation, tilt, location, cell position and bypass-diode configuration on the annual energy yield of bifacial photovoltaic noise barriers., Photovoltaic Materials and Devices, Electrical Sustainable Energy

Published
2018
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40. A photovoltaic window with sun-tracking shading elements towards maximum power generation and non-glare daylighting

Author

Gao, Y. (author), Dong, J. (author), Isabella, O. (author), Santbergen, R. (author), Tan, H. (author), Zeman, M. (author), Zhang, Kouchi (author), Gao, Y. (author), Dong, J. (author), Isabella, O. (author), Santbergen, R. (author), Tan, H. (author), Zeman, M. (author), and Zhang, Kouchi (author)

Abstract

Vertical space bears great potential of solar energy especially for congested urban areas, where photovoltaic (PV) windows in high-rise buildings can contribute to both power generation and daylight harvest. Previous studies on sun-tracking PV windows strayed into the trade-off between tracking performance and mutual shading, failing to achieve the maximum energy generation. Here we first build integrated models which couple the performance of sun-tracking PV windows to the rotation angles. Secondly, one-degree-of-freedom (DOF) and two-DOF sun tracking are mathematically proven to be not able to gain either maximum power generation or non-glare daylighting under reasonable assumptions. Then we derive the optimum rotation angles of the variable-pivot-three-degree-of-freedom (VP-3-DOF) sun-tracking elements and demonstrate that the optimum VP-3-DOF sun tracking can achieve the aforementioned goals. When the restriction of the proposed model is relaxed, the same performance can be achieved by the optimum one-DOF sun tracking with extended PV slats and particular design of cell layout, requiring less complicated mechanical structures. Simulation results of nine global cities show that the annual energy generation and average module efficiency are improved respectively by 27.40% and 19.17% via the optimum VP-3-DOF sun tracking over the conventional perpendicular sun tracking. The proposed optimum sun-tracking methods also reveal better protection against sun glare. The optimum VP-3-DOF sun tracking is also demonstrated to be applicable to horizontal PV windows, as those applied in the sun roof of a glass greenhouse., Photovoltaic Materials and Devices, Electrical Sustainable Energy, Electronic Components, Technology and Materials

Published
2018
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42. The role of oxide interlayers in back reflector configurations for amorphous silicon solar cells.

Author

Demontis, V., Sanna, C., Melskens, J., Santbergen, R., Smets, A. H. M., Damiano, A., and Zeman, M.

Subjects
LIGHTING reflectors, SOLAR cells, AMORPHOUS substances, PLASMA-enhanced chemical vapor deposition, REFLECTANCE
Abstract

Thin oxide interlayers are commonly added to the back reflector of thin-film silicon solar cells to increase their current. To gain more insight in the enhancement mechanism, we tested different back reflector designs consisting of aluminium-doped zinc oxide (ZnO:Al) and/or hydrogenated silicon oxide (SiOx:H) interlayers with different metals (silver, aluminium, and chromium) in standard p-i-n a-Si:H solar cells. We use a unique inverse modeling approach to show that in most back reflectors the internal metal reflectance is lower than expected theoretically. However, the metal reflectance is increased by the addition of an oxide interlayer. Our experiments demonstrate that SiOx:H forms an interesting alternative interlayer because unlike the more commonly used ZnO:Al it can be deposited by plasma-enhanced chemical vapour deposition and it does not reduce the fill factor. The largest efficiency enhancement is obtained with a double interlayer of SiOx:H and ZnO:Al. [ABSTRACT FROM AUTHOR]

Published
2013
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43. Material properties of LPCVD processed n-type polysilicon passivating contacts and its application in PERPoly industrial bifacial solar cells

Author

Stodolny, Maciej K. (author), Anker, John (author), Geerligs, Bart L.J. (author), Janssen, G.J.M. (author), Van De Loo, Bas W.H. (author), Melskens, J. (author), Santbergen, R. (author), Isabella, O. (author), Schmitz, Jurriaan (author), Lenes, Martijn (author), Luchies, Jan Marc (author), Kessels, W. (author), Romijn, I.G. (author), Stodolny, Maciej K. (author), Anker, John (author), Geerligs, Bart L.J. (author), Janssen, G.J.M. (author), Van De Loo, Bas W.H. (author), Melskens, J. (author), Santbergen, R. (author), Isabella, O. (author), Schmitz, Jurriaan (author), Lenes, Martijn (author), Luchies, Jan Marc (author), Kessels, W. (author), and Romijn, I.G. (author)

Abstract

We present a detailed material study of n+-type polysilicon (polySi) and its application as a carrier selective rear contact in a bifacial n-type solar cell comprising fire-through screen-printed metallization and 6" Cz wafers. The cells were manufactured with low-cost industrial process steps yielding Vocs from 676 to 683 mV and Jscs above 39.4 mA/cm2 indicating an efficiency potential of 22%. The aim of this study is to understand which material properties determine the performance of POCl3-diffused (n-type) polySi-based passivating contacts and to find routes to improve its use for industrial PERPoly (Passivated Emitter Rear PolySi) cells from the point of view of throughput, performance, and bifacial application. This paper reports on correlations between the parameters used for low pressure chemical vapour deposition (LPCVD), annealing, and doping on optical, structural, and electronic properties of the polySi-based passivating contact and the subsequent influence on the solar cell parameters., Photovoltaic Materials and Devices

Published
2017
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44. Calculation of irradiance distribution on PV modules by combining sky and sensitivity maps

Author

Santbergen, R. (author), Muthukumar, V.A. (author), Valckenborg, R.M.E. (author), van de Wall, W.J.A. (author), Smets, A.H.M. (author), Zeman, M. (author), Santbergen, R. (author), Muthukumar, V.A. (author), Valckenborg, R.M.E. (author), van de Wall, W.J.A. (author), Smets, A.H.M. (author), and Zeman, M. (author)

Abstract

Photovoltaic (PV) modules receive both direct light from the sun and scattered light from the sky, ground and nearby objects. The calculation of incident irradiance becomes complex when nearby objects cast shadows or reflect sunlight onto the PV modules. In this paper a flexible irradiance model is presented that takes all these effects into account by combining a so-called sky map, obtained from the Perez model, with a sensitivity map, generated using a ray tracing software. This irradiation model is validated for a PV facade that combines PV modules with mirror reflectors and is shown to be a flexible tool to accurately predict the irradiance distribution., Photovoltaic Materials and Devices, Electrical Sustainable Energy

Published
2017
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45. GenPro4 Optical Model for Solar Cell Simulation and Its Application to Multijunction Solar Cells

Author

Santbergen, R. (author), Meguro, Tomomi (author), Suezaki, Takashi (author), Koizumi, Gensuke (author), Yamamoto, Kenji (author), Zeman, M. (author), Santbergen, R. (author), Meguro, Tomomi (author), Suezaki, Takashi (author), Koizumi, Gensuke (author), Yamamoto, Kenji (author), and Zeman, M. (author)

Abstract

We present a new version of our optical model for solar cell simulation: GenPro4. Its working principles are briefly explained. The model is suitable for quickly and accurately simulating a wide range of wafer-based and thin-film solar cells. Especially adjusting layer thicknesses to match the currents in multijunction devices can be done with a minimum of computational cost. To illustrate this, a triple junction thin-film silicon solar cell is simulated. The simulation results show very good agreement with external quantum efficiency measurements. The application of an MgF2 antireflective coating or an antireflective foil with pyramid texture is considered. Their effects on the implied photocurrents of top, middle, and bottom cells are investigated in detail., Accepted author manuscript, Photovoltaic Materials and Devices, Electrical Sustainable Energy

Published
2017
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46. Material properties of LPCVD processed n-type polysilicon passivating contacts and its application in PERPoly industrial bifacial solar cells

Author

Stodolny, M.K., van den Anker, J., Geerligs, B.L.J., Janssen, G.J.M., van de Loo, B.W.H., Melskens, J., Santbergen, R., Isabella, O., Schmitz, J., Lenes, M., Luchies, J.M., Kessels, W.M.M., Romijn, I., Stodolny, M.K., van den Anker, J., Geerligs, B.L.J., Janssen, G.J.M., van de Loo, B.W.H., Melskens, J., Santbergen, R., Isabella, O., Schmitz, J., Lenes, M., Luchies, J.M., Kessels, W.M.M., and Romijn, I.

Abstract

We present a detailed material study of n+-type polysilicon (polySi) and its application as a carrier selective rear contact in a bifacial n-type solar cell comprising fire-through screen-printed metallization and 6" Cz wafers. The cells were manufactured with low-cost industrial process steps yielding Vocs from 676 to 683 mV and Jscs above 39.4 mA/cm2 indicating an efficiency potential of 22%. The aim of this study is to understand which material properties determine the performance of POCl3-diffused (n-type) polySi-based passivating contacts and to find routes to improve its use for industrial PERPoly (Passivated Emitter Rear PolySi) cells from the point of view of throughput, performance, and bifacial application. This paper reports on correlations between the parameters used for low pressure chemical vapour deposition (LPCVD), annealing, and doping on optical, structural, and electronic properties of the polySi-based passivating contact and the subsequent influence on the solar cell parameters.

Published
2017

47. Minimizing optical losses in monolithic perovskite/c-Si tandem solar cells with a flat top cell

Author

Santbergen, R. (author), Mishima, Ryoto (author), Meguro, Tomomi (author), Hino, Masashi (author), Uzu, Hisashi (author), Blanker, A.J. (author), Yamamoto, Kenji (author), Zeman, M. (author), Santbergen, R. (author), Mishima, Ryoto (author), Meguro, Tomomi (author), Hino, Masashi (author), Uzu, Hisashi (author), Blanker, A.J. (author), Yamamoto, Kenji (author), and Zeman, M. (author)

Abstract

In a monolithic perovskite/c-Si tandem device, the perovskite top cell has to be deposited onto a flat c-Si bottom cell without anti-reflective front side texture, to avoid fabrication issues. We use optical simulations to analyze the reflection losses that this induces. We then systematically minimize these losses by introducing surface textures in combination with a so-called burial layer to keep the perovskite top cell flat. Optical simulations show that, even with a flat top cell, the monolithic perovskite/c-Si tandem device can reach a matched photocurrent density as high as 19.57 mA/cm2., Photovoltaic Materials and Devices, Electrical Sustainable Energy

Published
2016
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48. Highly efficient hybrid polymer and amorphous silicon multijunction solar cells with effective optical management

Author

Tan, H., Furlan, A., Li, Weiwei, Arapov, K., Santbergen, R., Wienk, M.M., Zeman, M., Smets, A.H.M., Janssen, R.A.J., Tan, H., Furlan, A., Li, Weiwei, Arapov, K., Santbergen, R., Wienk, M.M., Zeman, M., Smets, A.H.M., and Janssen, R.A.J.

Abstract

Highly efficient hybrid multijunction solar cells are constructed with a wide-bandgap amorphous silicon for the front subcell and a low-bandgap polymer for the back subcell. Power conversion efficiencies of 11.6% and 13.2% are achieved in tandem and triple-junction configurations, respectively. The high efficiencies are enabled by deploying effective optical management and by using photoactive materials with complementary absorption.

Published
2016

49. Optical Simulation of Multi-junction Solar Cells

Author

Santbergen, R., primary, Mishima, R., additional, Meguro, T., additional, Suezaki, T., additional, Hino, M., additional, Uzu, H., additional, Koizumi, G., additional, Blanker, J., additional, Yamamoto, K., additional, and Zeman, M., additional

Published
2016
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50. Modelling Plasmonic Solar Cells

Author

Santbergen, R., Solntsev, S., and Zeman, M.

Subjects
Advanced Photovoltaics: New Concepts and Ultra-high Efficiency, Fundamental Studies
Abstract

25th European Photovoltaic Solar Energy Conference and Exhibition / 5th World Conference on Photovoltaic Energy Conversion, 6-10 September 2010, Valencia, Spain; 533-538, A new and promising light trapping technique for solar cells is based on the localised surface plasmon resonance of metal nanoparticles. To further optimise plasmonic light trapping, more insight is required in the behaviour of metal nanoparticles embedded in the complex optical structure of a solar cell. We show that the local strength of the driving field has a large effect on the optical properties of silver nanoparticles and that this effect can be taken into account using an effective medium approach. This allows for incorporation of plasmonic effects into an existing solar cell simulation program. We performed integrated optical and electrical simulations of hydrogenated amorphous silicon solar cells with embedded silver nanoparticles. These simulations show that parasitic absorption in silver nanoparticles can play an important role and should be minimised.

Published
2010
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