Design of Large Poly‐Si on Oxide Interdigitated Back Contact (POLO IBC) Silicon Solar Cells with Local Al–p + Contacts in the Constraints of Measurement and Module Integration

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Felix Haase
  • Christina Hollemann
  • Nadine Wehmeier
  • Karsten Bothe
  • Byungsul Min
  • Henning Schulte-Huxel
  • Rolf Brendel
  • Robby Peibst

Research Organisations

External Research Organisations

  • Institute for Solar Energy Research (ISFH)
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Details

Original languageEnglish
Article number2200583
Number of pages8
JournalSolar RRL
Volume6
Issue number11
Early online date15 Sept 2022
Publication statusPublished - 8 Nov 2022

Abstract

Interdigitated back contact (IBC) silicon solar cells with a passivating n-type poly-Si on oxide emitter and an aluminum-doped p+ base contact on M2-sized Ga-doped p-type Cz wafers are reported. The Al-doped base contact forms during the firing of the printed contacts and allows for a lean process flow. The device optimization balances recombination at the base contacts against resistive losses and respects constraints set by the need of interconnecting cells in a module and contacting the cells temporally by a measurement chuck. A special sample holder is designed for measuring the Isc–Voc curve of the IBC cell with a busbar-less metal grid. The pseudo-efficiency is 24.7%. All fingers of each polarity are connected with wires and an efficiency of 22.3% is measured. The comparison of simulations and measurements reveals that the cell has 23.4% efficiency without the series resistance losses due to the wires. A huge part of the resistive losses in the cell are the transport losses of the majorities in the base dissipating a power that corresponds to 0.76%abs efficiency and the resistive losses at the Al-doped base contact (0.29%abs).

Keywords

    current–voltage measurements, free energy loss analyses, POLO IBC, poly-silicon, simulations

ASJC Scopus subject areas

Cite this

Design of Large Poly‐Si on Oxide Interdigitated Back Contact (POLO IBC) Silicon Solar Cells with Local Al–p + Contacts in the Constraints of Measurement and Module Integration. / Haase, Felix; Hollemann, Christina; Wehmeier, Nadine et al.
In: Solar RRL, Vol. 6, No. 11, 2200583, 08.11.2022.

Research output: Contribution to journalArticleResearchpeer review

Haase, F., Hollemann, C., Wehmeier, N., Bothe, K., Min, B., Schulte-Huxel, H., Brendel, R., & Peibst, R. (2022). Design of Large Poly‐Si on Oxide Interdigitated Back Contact (POLO IBC) Silicon Solar Cells with Local Al–p + Contacts in the Constraints of Measurement and Module Integration. Solar RRL, 6(11), Article 2200583. https://doi.org/10.1002/solr.202200583
Haase F, Hollemann C, Wehmeier N, Bothe K, Min B, Schulte-Huxel H et al. Design of Large Poly‐Si on Oxide Interdigitated Back Contact (POLO IBC) Silicon Solar Cells with Local Al–p + Contacts in the Constraints of Measurement and Module Integration. Solar RRL. 2022 Nov 8;6(11):2200583. Epub 2022 Sept 15. doi: 10.1002/solr.202200583
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title = "Design of Large Poly‐Si on Oxide Interdigitated Back Contact (POLO IBC) Silicon Solar Cells with Local Al–p + Contacts in the Constraints of Measurement and Module Integration",
abstract = "Interdigitated back contact (IBC) silicon solar cells with a passivating n-type poly-Si on oxide emitter and an aluminum-doped p+ base contact on M2-sized Ga-doped p-type Cz wafers are reported. The Al-doped base contact forms during the firing of the printed contacts and allows for a lean process flow. The device optimization balances recombination at the base contacts against resistive losses and respects constraints set by the need of interconnecting cells in a module and contacting the cells temporally by a measurement chuck. A special sample holder is designed for measuring the Isc–Voc curve of the IBC cell with a busbar-less metal grid. The pseudo-efficiency is 24.7%. All fingers of each polarity are connected with wires and an efficiency of 22.3% is measured. The comparison of simulations and measurements reveals that the cell has 23.4% efficiency without the series resistance losses due to the wires. A huge part of the resistive losses in the cell are the transport losses of the majorities in the base dissipating a power that corresponds to 0.76%abs efficiency and the resistive losses at the Al-doped base contact (0.29%abs).",
keywords = "current–voltage measurements, free energy loss analyses, POLO IBC, poly-silicon, simulations",
author = "Felix Haase and Christina Hollemann and Nadine Wehmeier and Karsten Bothe and Byungsul Min and Henning Schulte-Huxel and Rolf Brendel and Robby Peibst",
note = "Funding Information: The authors would like to thank A. Christ, D. Sylla, A. Raugewitz, R. Winter, M. Pollmann, T. Neubert, U. Baumann, S. Blankemeyer, I. Kunze (all ISFH), and R. Zieseni{\ss} (Institute of Electronic Materials and Devices) for sample processing and measuring, and B. Fischer (pv‐tools) for designing and calibrating the measurement chuck. The authors also thank TOYO Aluminum for providing the Al‐paste, Heraeus, and Dupont for the Ag‐pastes, and LONGI for providing the wafer material. This work was funded by the state of Lower Saxony and the Federal Ministry for Economic Affairs and Climate Action (BMWK) under grant number 0324275A (Street). ",
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T1 - Design of Large Poly‐Si on Oxide Interdigitated Back Contact (POLO IBC) Silicon Solar Cells with Local Al–p + Contacts in the Constraints of Measurement and Module Integration

AU - Haase, Felix

AU - Hollemann, Christina

AU - Wehmeier, Nadine

AU - Bothe, Karsten

AU - Min, Byungsul

AU - Schulte-Huxel, Henning

AU - Brendel, Rolf

AU - Peibst, Robby

N1 - Funding Information: The authors would like to thank A. Christ, D. Sylla, A. Raugewitz, R. Winter, M. Pollmann, T. Neubert, U. Baumann, S. Blankemeyer, I. Kunze (all ISFH), and R. Zieseniß (Institute of Electronic Materials and Devices) for sample processing and measuring, and B. Fischer (pv‐tools) for designing and calibrating the measurement chuck. The authors also thank TOYO Aluminum for providing the Al‐paste, Heraeus, and Dupont for the Ag‐pastes, and LONGI for providing the wafer material. This work was funded by the state of Lower Saxony and the Federal Ministry for Economic Affairs and Climate Action (BMWK) under grant number 0324275A (Street).

PY - 2022/11/8

Y1 - 2022/11/8

N2 - Interdigitated back contact (IBC) silicon solar cells with a passivating n-type poly-Si on oxide emitter and an aluminum-doped p+ base contact on M2-sized Ga-doped p-type Cz wafers are reported. The Al-doped base contact forms during the firing of the printed contacts and allows for a lean process flow. The device optimization balances recombination at the base contacts against resistive losses and respects constraints set by the need of interconnecting cells in a module and contacting the cells temporally by a measurement chuck. A special sample holder is designed for measuring the Isc–Voc curve of the IBC cell with a busbar-less metal grid. The pseudo-efficiency is 24.7%. All fingers of each polarity are connected with wires and an efficiency of 22.3% is measured. The comparison of simulations and measurements reveals that the cell has 23.4% efficiency without the series resistance losses due to the wires. A huge part of the resistive losses in the cell are the transport losses of the majorities in the base dissipating a power that corresponds to 0.76%abs efficiency and the resistive losses at the Al-doped base contact (0.29%abs).

AB - Interdigitated back contact (IBC) silicon solar cells with a passivating n-type poly-Si on oxide emitter and an aluminum-doped p+ base contact on M2-sized Ga-doped p-type Cz wafers are reported. The Al-doped base contact forms during the firing of the printed contacts and allows for a lean process flow. The device optimization balances recombination at the base contacts against resistive losses and respects constraints set by the need of interconnecting cells in a module and contacting the cells temporally by a measurement chuck. A special sample holder is designed for measuring the Isc–Voc curve of the IBC cell with a busbar-less metal grid. The pseudo-efficiency is 24.7%. All fingers of each polarity are connected with wires and an efficiency of 22.3% is measured. The comparison of simulations and measurements reveals that the cell has 23.4% efficiency without the series resistance losses due to the wires. A huge part of the resistive losses in the cell are the transport losses of the majorities in the base dissipating a power that corresponds to 0.76%abs efficiency and the resistive losses at the Al-doped base contact (0.29%abs).

KW - current–voltage measurements

KW - free energy loss analyses

KW - POLO IBC

KW - poly-silicon

KW - simulations

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U2 - 10.1002/solr.202200583

DO - 10.1002/solr.202200583

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VL - 6

JO - Solar RRL

JF - Solar RRL

IS - 11

M1 - 2200583

ER -