Perovskite modules with 99% geometrical fill factor using point contact interconnections design

The performance of hybrid organic–inorganic perovskite solar cells has reached a certified efficiency of 25.5% over the past decade, which has attracted significant attention as a promising candidate for photovoltaic (PV) applications. However, the most efficient perovskite solar cells were produced by the technique of spin coating, which is extremely limited in terms of upscaling production for the commercialization of the technology. Furthermore, the efficiencies of large‐area perovskite modules are still significantly lower than those of lab size solar cells. Thus, there are still some challenges that need to be overcome to bridge the efficiency gap between small‐area perovskite solar cells and large‐area perovskite devices. The first challenge lies in preparing high‐quality perovskite layers by low‐cost and scalable techniques with high reproducibility. Second, selecting and depositing charge extraction layers as well as bottom and top electrodes by scalable and low‐cost techniques are essential tasks. In this review, recent progress and challenges of scalable technologies for solution‐based coating and printing of perovskite PVs are summarized and analyzed. Based on the analysis, strategies and opportunities are proposed to promote the development of stable and efficient large‐area perovskite PV toward commercialization.

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“…As a result, perovskite modules fabricated through all‐laser scribing have achieved a GFF of up to 99%. [ 122 ]…”

Section: Module Designmentioning

confidence: 99%

Upscaling Solution‐Processed Perovskite Photovoltaics

Yang

Jang

Dong

et al. 2021

Advanced Energy Materials

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“…In that regard, the concept of point interconnections recently introduced by Rakocevic et al for perovskite minimodules might also be of significant interest for further development. 102 Furthermore, the strong analogy of the developed approach to the manufacturing of established thin-film technologies potentially benefits further upscaling via knowledge transfer. For instance, the common utilization of additional scanner lens systems to increase module width and throughput is expected to enable the fabrication of modules of several hundred square centimeters with GFFs of 96% or above.…”

Section: Efficient Upscaling Of All-laser-scribed Allevaporated Perov...mentioning

confidence: 99%

“…As a consequence of the solar module interconnection, two loss mechanisms arise, namely, (1) contact resistance at the interconnections and (2) a reduction of the active area required for the interconnection. 101,102 Therefore, in order to maximize performance in thin-film PV modules, it is crucial to minimize these individual losses by employing suitable scribing methods and interconnection layouts. Realization of the three essential interconnection lines (commonly referred to as P1, P2, and P3) is performed via either mechanical scribing, 103 chemical etching, lift-off processes, 27,104 laser scribing, 59 or a combination of these methods.…”

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confidence: 99%

“…59 Furthermore, by developing a laser-scribed point contact interconnection scheme, Rakocevic et al have shown that the active area loss can be reduced to as little as 1% rel for a 4-cm 2 aperture area device. 102 It should be noted that most previous studies on all-laser-scribed interconnections of perovskite minimodules used more than one lasing source to process all three interconnection lines (e.g., with different wavelengths) and in many cases picosecond and femtosecond laser sources were applied. 59,69,[112][113][114] While shorter pulses commonly allow for more selective laser ablation, the complexity and also price of such lasing sources increases below 100 picoseconds.…”

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confidence: 99%

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Upscaling of perovskite solar modules: The synergy of fully evaporated layer fabrication and all‐laser‐scribed interconnections

Ritzer

Abzieher

Basibüyük

et al. 2021

Progress in Photovoltaics

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Given the outstanding progress in research over the past decade, perovskite photovoltaics (PV) is about to step up from laboratory prototypes to commercial products.For this to happen, realizing scalable processes to allow the technology to transition from solar cells to modules is pivotal. This work presents all-evaporated perovskite PV modules with all thin films coated by established vacuum deposition processes. A common 532-nm nanosecond laser source is employed to realize all three interconnection lines of the solar modules. The resulting module interconnections exhibit low series resistance and a small total lateral extension down to 160 μm. In comparison with interconnection fabrication approaches utilizing multiple scribing tools, the process complexity is reduced while the obtained geometrical fill factor of 96% is comparable with established inorganic thin-film PV technologies. The all-evaporated perovskite minimodules demonstrate power conversion efficiencies of 18.0% and 16.6% on aperture areas of 4 and 51 cm 2 , respectively. Most importantly, the allevaporated minimodules exhibit only minimal upscaling losses as low as 3.1% rel per decade of upscaled area, at the same time being the most efficient perovskite PV minimodules based on an all-evaporated layer stack sequence.

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“…Nevertheless, the commercialization of PSC still faces key challenges that need to be addressed to make this technology competitive: 1) long‐term stability [ 3,4 ] and 2) device area upscaling. [ 5–7 ] Critical aspects of PSCs upscaling are obtaining homogeneous perovskite absorber layer properties and selective contacts, [ 8,9 ] as well as minimal resistive losses. [ 5,10,11 ] Development of suitable characterization techniques, which can reliably and rapidly identify the factors contributing to these two main issues, is essential.…”

Section: Introductionmentioning

confidence: 99%

Contactless Series Resistance Imaging of Perovskite Solar Cells via Inhomogeneous Illumination

et al. 2021

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A contactless effective series resistance imaging method for large‐area perovskite solar cells that is based on photoluminescence imaging with nonuniform illumination is introduced and demonstrated experimentally. The proposed technique is applicable to partially and fully processed perovskite solar cells if laterally conductive layers are present. The capability of the proposed contactless method to detect features with high effective series resistance is validated by comparison with various contacted mode luminescence imaging techniques. The method can reliably provide information regarding the severeness of the detected series resistance through photoexcitation pattern manipulation. Application of the method to subcells in monolithic tandem devices, without the need for electrical contacting the terminals, appears feasible.

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Perovskite modules with 99% geometrical fill factor using point contact interconnections design

Cited by 25 publications

References 22 publications

Upscaling Solution‐Processed Perovskite Photovoltaics

Upscaling Solution‐Processed Perovskite Photovoltaics

Upscaling of perovskite solar modules: The synergy of fully evaporated layer fabrication and all‐laser‐scribed interconnections

Contactless Series Resistance Imaging of Perovskite Solar Cells via Inhomogeneous Illumination

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