Combined Fabrication and Performance Evaluation of TOPCon Back‐Contact Solar Cells with Lateral Power Metal‐Oxide‐Semiconductor Field‐Effect Transistors on a Single Substrate

Nowadays, an increasing share of photovoltaic (PV) systems makes use of module‐ or submodule‐level power electronics (PE). Furthermore, PE is used in stand‐alone devices powered by PV‐storage solutions. One way to facilitate further implementation of PE in PV applications is to integrate PE componen...

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Veröffentlicht in:	Solar RRL 2024-05, Vol.8 (9), p.n/a
Hauptverfasser:	van Nijen, David A., Stevens, Tristan, Mercimek, Yavuzhan, Yang, Guangtao, van Swaaij, René A.C.M.M., Zeman, Miro, Isabella, Olindo, Manganiello, Patrizio
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Sprache:	eng
Schlagworte:	COSMOS crystalline silicon integration interdigitated back contact monolithic integration MOSFET photovoltatronics polycrystalline silicon on oxide power electronics tunnel‐oxide passivated contacts
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container_title	Solar RRL
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creator	van Nijen, David A. Stevens, Tristan Mercimek, Yavuzhan Yang, Guangtao van Swaaij, René A.C.M.M. Zeman, Miro Isabella, Olindo Manganiello, Patrizio
description	Nowadays, an increasing share of photovoltaic (PV) systems makes use of module‐ or submodule‐level power electronics (PE). Furthermore, PE is used in stand‐alone devices powered by PV‐storage solutions. One way to facilitate further implementation of PE in PV applications is to integrate PE components into crystalline silicon PV cells. Herein, the COSMOS device is introduced, denoting COmbined Solar cell and metal‐oxide‐semiconductor field‐effect transistor (MOSFET). Specifically, the combined manufacturing of lateral power MOSFETs and interdigitated back contact solar cells with tunnel‐oxide passivated contacts (TOPCon) on a single wafer is reported. Many steps of the proposed process flow are used for the fabrication of both devices, enabling cost‐effective integration of the MOSFET. Both n‐type solar cells with integrated p‐channel MOSFETs (PMOS) and p‐type solar cells with integrated n‐channel MOSFETs (NMOS) are successfully manufactured. NMOS devices perform better in achieving low on‐resistance, while PMOS devices exhibit lower leakage currents. Furthermore, the study reveals integration challenges where off‐state leakage currents of the MOSFET can increase due to illumination and specific configurations of monolithic interconnections between the MOSFET and the solar cell. Nevertheless, for both n‐type and p‐type solar cells, efficiencies exceeding 20% are achieved, highlighting the potential of the proposed process for COSMOS devices. The COSMOS device, which denotes Combined Solar cell and metal‐oxide‐semiconductor field‐effect transistor (MOSFET) technology, represents an innovative integration of power MOSFETs into crystalline silicon solar cells. The article highlights the combined manufacturing process of TOPCon back‐contact solar cells with lateral power MOSFETs, shows solar cell efficiencies over 20%, and explores interactions between the components.
doi_str_mv	10.1002/solr.202300829
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Furthermore, the study reveals integration challenges where off‐state leakage currents of the MOSFET can increase due to illumination and specific configurations of monolithic interconnections between the MOSFET and the solar cell. Nevertheless, for both n‐type and p‐type solar cells, efficiencies exceeding 20% are achieved, highlighting the potential of the proposed process for COSMOS devices. The COSMOS device, which denotes Combined Solar cell and metal‐oxide‐semiconductor field‐effect transistor (MOSFET) technology, represents an innovative integration of power MOSFETs into crystalline silicon solar cells. 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subjects	COSMOS crystalline silicon integration interdigitated back contact monolithic integration MOSFET photovoltatronics polycrystalline silicon on oxide power electronics tunnel‐oxide passivated contacts
title	Combined Fabrication and Performance Evaluation of TOPCon Back‐Contact Solar Cells with Lateral Power Metal‐Oxide‐Semiconductor Field‐Effect Transistors on a Single Substrate
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