Boron‐doped polysilicon using spin‐on doping for high‐efficiency both‐side passivating contact silicon solar cells

Park, HyunJung; Kim, Jinsol; Choi, Dongjin; Lee, Sang‐Won; Kang, Dongkyun; Lee, Hae‐Seok; Kim, Dong Hwan; Kim, Munho; Kang, Yoonmook

doi:10.1002/pip.3648

Cited by 6 publications

(2 citation statements)

References 50 publications

(128 reference statements)

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“… 26 Hence, utilizing a homojunction solar cell as the bottom cell is advantageous for the industrialization of tandem cells. Owing to their high-temperature tolerance, 27 , 28 TOPCon cells are fully compatible with the current manufacturing processes for PERC and highly efficient perovskite top cells. Reportedly, TOPCon cells have exhibited an efficiency of 26.7%, 12 indicating their potential as bottom cells in tandem solar cells.…”

Section: Introductionmentioning

confidence: 99%

Titanium Silicide: A Promising Candidate of Recombination Layer for Perovskite/Tunnel Oxide Passivated Contact Silicon Two-Terminal Tandem Solar Cells

Pyun,

Choi,

Bae

et al. 2024

ACS Appl. Mater. Interfaces

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This study proposes a titanium silicide (TiSi2) recombination layer for perovskite/tunnel oxide passivated contact (TOPCon) 2-T tandem solar cells as an alternative to conventional transparent conductive oxide (TCO)-based recombination layers. TiSi2 was formed while TiO2 was made by oxidizing a Ti film deposited on the p+-Si layer. The reaction formation mechanism was proposed based on the diffusion theory supported by experimental results. The optical and electrical properties of the TiSi2 layer were optimized by controlling the initial Ti thicknesses (5–100 nm). With the initial Ti of 50 nm, the lowest reflectance and highly ohmic contact between the TiO2 and p+-Si layers with a contact resistivity of 161.48 mΩ·cm2 were obtained. In contrast, the TCO interlayer shows Schottky behavior with much higher contact resistivities. As the recombination layer of TiSi2 and the electron transport layer of TiO2 are formed simultaneously, the process steps become simpler. Finally, the MAPbI3/TOPCon tandem device yielded an efficiency of 16.23%, marking the first reported efficiency for a device including a silicide-based interlayer.

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Section: Introductionmentioning

confidence: 99%

Titanium Silicide: A Promising Candidate of Recombination Layer for Perovskite/Tunnel Oxide Passivated Contact Silicon Two-Terminal Tandem Solar Cells

Pyun,

Choi,

Bae

et al. 2024

ACS Appl. Mater. Interfaces

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“…it connects to the silicon wafer with low contact resistance and simultaneously provides surface passivation. In this study, we focused on high-temperature passivating contacts (HTPC) [11,12,13,14] and their integration into p + /n + SiCx tunnel junctions. These are considered a promising design for the bottom cell for several reasons: the optically preferred n-i-p configuration can be used for the top cell, they pose fewer limitations on top cell process temperature (permitting a broader choice for materials and processes), their high crystallinity ensures low parasitic absorption and high transverse conductivity, and different from TCO-based TJs, their deposition does not create sputter damage.…”

Section: Introductionmentioning

confidence: 99%

Polysilicon-based tunnel junction Si solar cells with machine learning for tandem cell applications

Park

Morisset

Kim

et al. 2023

Preprint

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Tandem solar cells are a key technology to exceed the theoretical efficiency limit of single-junction cells. One of the most promising combinations is the silicon-perovskite tandem cells, considering their potential for high efficiency, large-area fabrication, and low cost. Whereas most research focuses on improvements in each subcell, another key challenge relies on the tunnel junction that connects subcells and affects overall cell characteristics. Here, the first demonstration of tunnel junctions using a stack of p/n polysilicon deposited directly on the passivating tunnel oxide are shown to overcome the drawbacks of conventional metal oxide-based tunnel junctions including low tunneling efficiency and sputter damage. Furthermore, using Random Forest analysis, high implied open circuit voltages over 700 mV in the bottom cell with the polysilicon tunnel junction are achieved. Their contact resistivities are as low as 500 mΩ·cm, suggesting FF losses of less than 1 %abs for the operating conditions of a tandem cell.

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Data‐Driven Tunnel Oxide Passivated Contact Solar Cell Performance Analysis Using Machine Learning

Zhou,

Jacobsson,

Wang

et al. 2024

Advanced Materials

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Tunnel oxide passivated contacts (TOPCon) have recently gained interest as a way to increase the energy conversion efficiency of silicon solar cells, and the International Technology Roadmap of Photovoltaics forecasts TOPCon to become an important technology despite a few remaining challenges. To review the recent development of TOPCon cells, we have compiled a dataset of all device data found in the current literature, which sums up to 405 devices from 131 papers. This may seem like a surprisingly small number of cells given the recent interest in the TOPCon architecture, but it illustrates a problem of data dissemination in the field. Notwithstanding the limited number of cells, there is a great diversity in cell manufacturing procedures, and we observe a gradual increase in performance indicating that the field has not yet converged on a set of best practices. By analyzing the data using statistical methods and machine learning (ML) algorithms, we were able to reinforces some commonly held hypotheses related to the performance differences between different device architectures. We also identify a few more unintuitive feature combinations that would be of interest for further experimentally studies. This work also aims to inspire improvements in data management and dissemination within the TOPCon community, which would further increase the value of statistical analysis like this as well as enable a larger part of the ML toolbox to be used.This article is protected by copyright. All rights reserved

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Boron‐doped polysilicon using spin‐on doping for high‐efficiency both‐side passivating contact silicon solar cells

Cited by 6 publications

References 50 publications

Titanium Silicide: A Promising Candidate of Recombination Layer for Perovskite/Tunnel Oxide Passivated Contact Silicon Two-Terminal Tandem Solar Cells

Titanium Silicide: A Promising Candidate of Recombination Layer for Perovskite/Tunnel Oxide Passivated Contact Silicon Two-Terminal Tandem Solar Cells

Polysilicon-based tunnel junction Si solar cells with machine learning for tandem cell applications

Data‐Driven Tunnel Oxide Passivated Contact Solar Cell Performance Analysis Using Machine Learning

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