Industrial implementation of 24%-efficient POLO IBC solar cells and future upgrade to 26%-efficient POLO2IBC

Publikation: Beitrag in FachzeitschriftArtikelTransferPeer-Review

Autorschaft

  • Thorsten Dullweber
  • Yevgeniya Larionova
  • Philip Jäger
  • Verena Mertens
  • Sabrina Schimanke
  • Melanie Ripke
  • Ulrike Baumann
  • Alaa Osman
  • Udo Römer
  • Robby Peibst
  • Rolf Brendel
  • Özlem Coşkun
  • Gamze Çekerek
  • Meriç Çalişkan Arslan
  • Geoffrey Gregory
  • Erik Hoffmann
  • Massimo Centazzo

Organisationseinheiten

Externe Organisationen

  • Institut für Solarenergieforschung GmbH (ISFH)
  • Baskent Organized Industrial Zone
  • EnPV GmbH
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Aufsatznummer30
FachzeitschriftEPJ Photovoltaics
Jahrgang16
PublikationsstatusVeröffentlicht - 27 Nov. 2025

Abstract

IBC solar cells have gained tremendous interest in the PV industry as next-generation technology. ISFH has developed a lean manufacturing process sequence for POLO IBC solar cells applying p-type Cz wafers, an Al-BSF base contact and local PECVD deposition of the SiOxNy/n-type polysilicon emitter through a glass shadow mask. In this paper, we report a new best POLO IBC cell efficiency of 24.5% processed at ISFH on M2 wafer size. In 2024, we started to transfer the POLO IBC process from the ISFH SolarTeC to the Kalyon PV manufacturing line using their M10 sized p-type Ga-doped Cz wafers and cell production tools. With Kalyon PV's wet chemistry and PECVD AlOx/SiN tools good surface passivation is demonstrated by obtaining an iVoc up to 727mV using textured, rear side polished AlOx/SiN passivated test wafers. Kalyon PV targets to process first M10-sized POLO IBC solar cells till end of 2025. However, the POLO IBC efficiency will be limited to below 25.5% by the carrier recombination at the Al-BSF base contact. To overcome this limitation aiming at n-type poly / p-type polysilicon POLO2 IBC cell efficiencies beyond 26%, EnPV and ISFH optimized a carrier selective SiOx/p-type polysilicon layer stack yielding a new best median saturation current density J0 =4±1 fA/cm2 using industrial tools for the wet chemically grown SiOx and the in-situ doped p-type polysilicon layer. ISFH is applying the SiOx/p-type polysilicon layer stack to develop a novel industrial processing sequence for the POLO2 IBC solar cell. We deposit both polysilicon layers in-situ-doped full-area and laser-structure both polysilicon polarities. Using lab-type tools and p-type float zone (FZ) wafers, a small-area POLO2 IBC solar cell with 25.5% efficiency has been developed at ISFH. Using M2-sized n-type Cz wafers, a novel IBC trench patterning process, and solely industrial processing tools in the ISFH SolarTeC targeting very cost-effective processes for etch barrier formation, laser structuring, and polysilicon etching, we obtain a measured implied Voc =735mV of POLO2 IBC cells processed without metal contacts. Since the polysilicon contacts minimize carrier recombination at metal contacts, the implied Voc value demonstrates the high Voc potential of this promising new POLO2 IBC manufacturing process thereby indicating a conversion efficiency potential above 26%.

ASJC Scopus Sachgebiete

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Industrial implementation of 24%-efficient POLO IBC solar cells and future upgrade to 26%-efficient POLO2IBC. / Dullweber, Thorsten; Larionova, Yevgeniya; Jäger, Philip et al.
in: EPJ Photovoltaics, Jahrgang 16, 30, 27.11.2025.

Publikation: Beitrag in FachzeitschriftArtikelTransferPeer-Review

Dullweber, T, Larionova, Y, Jäger, P, Mertens, V, Schimanke, S, Ripke, M, Baumann, U, Osman, A, Römer, U, Peibst, R, Brendel, R, Coşkun, Ö, Çekerek, G, Çalişkan Arslan, M, Gregory, G, Hoffmann, E & Centazzo, M 2025, 'Industrial implementation of 24%-efficient POLO IBC solar cells and future upgrade to 26%-efficient POLO2IBC', EPJ Photovoltaics, Jg. 16, 30. https://doi.org/10.1051/epjpv/2025019
Dullweber, T., Larionova, Y., Jäger, P., Mertens, V., Schimanke, S., Ripke, M., Baumann, U., Osman, A., Römer, U., Peibst, R., Brendel, R., Coşkun, Ö., Çekerek, G., Çalişkan Arslan, M., Gregory, G., Hoffmann, E., & Centazzo, M. (2025). Industrial implementation of 24%-efficient POLO IBC solar cells and future upgrade to 26%-efficient POLO2IBC. EPJ Photovoltaics, 16, Artikel 30. https://doi.org/10.1051/epjpv/2025019
Dullweber T, Larionova Y, Jäger P, Mertens V, Schimanke S, Ripke M et al. Industrial implementation of 24%-efficient POLO IBC solar cells and future upgrade to 26%-efficient POLO2IBC. EPJ Photovoltaics. 2025 Nov 27;16:30. doi: 10.1051/epjpv/2025019
Dullweber, Thorsten ; Larionova, Yevgeniya ; Jäger, Philip et al. / Industrial implementation of 24%-efficient POLO IBC solar cells and future upgrade to 26%-efficient POLO2IBC. in: EPJ Photovoltaics. 2025 ; Jahrgang 16.
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title = "Industrial implementation of 24%-efficient POLO IBC solar cells and future upgrade to 26%-efficient POLO2IBC",
abstract = "IBC solar cells have gained tremendous interest in the PV industry as next-generation technology. ISFH has developed a lean manufacturing process sequence for POLO IBC solar cells applying p-type Cz wafers, an Al-BSF base contact and local PECVD deposition of the SiOxNy/n-type polysilicon emitter through a glass shadow mask. In this paper, we report a new best POLO IBC cell efficiency of 24.5% processed at ISFH on M2 wafer size. In 2024, we started to transfer the POLO IBC process from the ISFH SolarTeC to the Kalyon PV manufacturing line using their M10 sized p-type Ga-doped Cz wafers and cell production tools. With Kalyon PV's wet chemistry and PECVD AlOx/SiN tools good surface passivation is demonstrated by obtaining an iVoc up to 727mV using textured, rear side polished AlOx/SiN passivated test wafers. Kalyon PV targets to process first M10-sized POLO IBC solar cells till end of 2025. However, the POLO IBC efficiency will be limited to below 25.5% by the carrier recombination at the Al-BSF base contact. To overcome this limitation aiming at n-type poly / p-type polysilicon POLO2 IBC cell efficiencies beyond 26%, EnPV and ISFH optimized a carrier selective SiOx/p-type polysilicon layer stack yielding a new best median saturation current density J0 =4±1 fA/cm2 using industrial tools for the wet chemically grown SiOx and the in-situ doped p-type polysilicon layer. ISFH is applying the SiOx/p-type polysilicon layer stack to develop a novel industrial processing sequence for the POLO2 IBC solar cell. We deposit both polysilicon layers in-situ-doped full-area and laser-structure both polysilicon polarities. Using lab-type tools and p-type float zone (FZ) wafers, a small-area POLO2 IBC solar cell with 25.5% efficiency has been developed at ISFH. Using M2-sized n-type Cz wafers, a novel IBC trench patterning process, and solely industrial processing tools in the ISFH SolarTeC targeting very cost-effective processes for etch barrier formation, laser structuring, and polysilicon etching, we obtain a measured implied Voc =735mV of POLO2 IBC cells processed without metal contacts. Since the polysilicon contacts minimize carrier recombination at metal contacts, the implied Voc value demonstrates the high Voc potential of this promising new POLO2 IBC manufacturing process thereby indicating a conversion efficiency potential above 26%.",
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year = "2025",
month = nov,
day = "27",
doi = "10.1051/epjpv/2025019",
language = "English",
volume = "16",
journal = "EPJ Photovoltaics",
issn = "2105-0716",
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TY - JOUR

T1 - Industrial implementation of 24%-efficient POLO IBC solar cells and future upgrade to 26%-efficient POLO2IBC

AU - Dullweber, Thorsten

AU - Larionova, Yevgeniya

AU - Jäger, Philip

AU - Mertens, Verena

AU - Schimanke, Sabrina

AU - Ripke, Melanie

AU - Baumann, Ulrike

AU - Osman, Alaa

AU - Römer, Udo

AU - Peibst, Robby

AU - Brendel, Rolf

AU - Coşkun, Özlem

AU - Çekerek, Gamze

AU - Çalişkan Arslan, Meriç

AU - Gregory, Geoffrey

AU - Hoffmann, Erik

AU - Centazzo, Massimo

N1 - Publisher Copyright: © T. Dullweber et al., Published by EDP Sciences, 2025.

PY - 2025/11/27

Y1 - 2025/11/27

N2 - IBC solar cells have gained tremendous interest in the PV industry as next-generation technology. ISFH has developed a lean manufacturing process sequence for POLO IBC solar cells applying p-type Cz wafers, an Al-BSF base contact and local PECVD deposition of the SiOxNy/n-type polysilicon emitter through a glass shadow mask. In this paper, we report a new best POLO IBC cell efficiency of 24.5% processed at ISFH on M2 wafer size. In 2024, we started to transfer the POLO IBC process from the ISFH SolarTeC to the Kalyon PV manufacturing line using their M10 sized p-type Ga-doped Cz wafers and cell production tools. With Kalyon PV's wet chemistry and PECVD AlOx/SiN tools good surface passivation is demonstrated by obtaining an iVoc up to 727mV using textured, rear side polished AlOx/SiN passivated test wafers. Kalyon PV targets to process first M10-sized POLO IBC solar cells till end of 2025. However, the POLO IBC efficiency will be limited to below 25.5% by the carrier recombination at the Al-BSF base contact. To overcome this limitation aiming at n-type poly / p-type polysilicon POLO2 IBC cell efficiencies beyond 26%, EnPV and ISFH optimized a carrier selective SiOx/p-type polysilicon layer stack yielding a new best median saturation current density J0 =4±1 fA/cm2 using industrial tools for the wet chemically grown SiOx and the in-situ doped p-type polysilicon layer. ISFH is applying the SiOx/p-type polysilicon layer stack to develop a novel industrial processing sequence for the POLO2 IBC solar cell. We deposit both polysilicon layers in-situ-doped full-area and laser-structure both polysilicon polarities. Using lab-type tools and p-type float zone (FZ) wafers, a small-area POLO2 IBC solar cell with 25.5% efficiency has been developed at ISFH. Using M2-sized n-type Cz wafers, a novel IBC trench patterning process, and solely industrial processing tools in the ISFH SolarTeC targeting very cost-effective processes for etch barrier formation, laser structuring, and polysilicon etching, we obtain a measured implied Voc =735mV of POLO2 IBC cells processed without metal contacts. Since the polysilicon contacts minimize carrier recombination at metal contacts, the implied Voc value demonstrates the high Voc potential of this promising new POLO2 IBC manufacturing process thereby indicating a conversion efficiency potential above 26%.

AB - IBC solar cells have gained tremendous interest in the PV industry as next-generation technology. ISFH has developed a lean manufacturing process sequence for POLO IBC solar cells applying p-type Cz wafers, an Al-BSF base contact and local PECVD deposition of the SiOxNy/n-type polysilicon emitter through a glass shadow mask. In this paper, we report a new best POLO IBC cell efficiency of 24.5% processed at ISFH on M2 wafer size. In 2024, we started to transfer the POLO IBC process from the ISFH SolarTeC to the Kalyon PV manufacturing line using their M10 sized p-type Ga-doped Cz wafers and cell production tools. With Kalyon PV's wet chemistry and PECVD AlOx/SiN tools good surface passivation is demonstrated by obtaining an iVoc up to 727mV using textured, rear side polished AlOx/SiN passivated test wafers. Kalyon PV targets to process first M10-sized POLO IBC solar cells till end of 2025. However, the POLO IBC efficiency will be limited to below 25.5% by the carrier recombination at the Al-BSF base contact. To overcome this limitation aiming at n-type poly / p-type polysilicon POLO2 IBC cell efficiencies beyond 26%, EnPV and ISFH optimized a carrier selective SiOx/p-type polysilicon layer stack yielding a new best median saturation current density J0 =4±1 fA/cm2 using industrial tools for the wet chemically grown SiOx and the in-situ doped p-type polysilicon layer. ISFH is applying the SiOx/p-type polysilicon layer stack to develop a novel industrial processing sequence for the POLO2 IBC solar cell. We deposit both polysilicon layers in-situ-doped full-area and laser-structure both polysilicon polarities. Using lab-type tools and p-type float zone (FZ) wafers, a small-area POLO2 IBC solar cell with 25.5% efficiency has been developed at ISFH. Using M2-sized n-type Cz wafers, a novel IBC trench patterning process, and solely industrial processing tools in the ISFH SolarTeC targeting very cost-effective processes for etch barrier formation, laser structuring, and polysilicon etching, we obtain a measured implied Voc =735mV of POLO2 IBC cells processed without metal contacts. Since the polysilicon contacts minimize carrier recombination at metal contacts, the implied Voc value demonstrates the high Voc potential of this promising new POLO2 IBC manufacturing process thereby indicating a conversion efficiency potential above 26%.

KW - back contact

KW - IBC

KW - passivating contacts

KW - POLO

KW - polysilicon

KW - Silicon solar cells

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UR - http://www.isfh.de

U2 - 10.1051/epjpv/2025019

DO - 10.1051/epjpv/2025019

M3 - Article

AN - SCOPUS:105023050337

VL - 16

JO - EPJ Photovoltaics

JF - EPJ Photovoltaics

SN - 2105-0716

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