Screen-Printed SHJ Solar Cells with Complex Silver Inks

Thien Truong; Matt Page; Sneh Sinha; Markus Kaupa; Mitchell Smith; Jennifer Selvidge; Harvey Guthrey; William Nemeth; San Theingi; Brett Walker; Myles Steiner; Paul Stradins; Melbs Lemieux; David Young

doi:10.2172/3017377

Screen-Printed SHJ Solar Cells with Complex Silver Inks

Thien Truong
, Matt Page
, Sneh Sinha
, Markus Kaupa
, Mitchell Smith
, Jennifer Selvidge
, Harvey Guthrey
, William Nemeth
, San Theingi
, Brett Walker
, Myles Steiner
, Paul Stradins
, Melbs Lemieux
, David Young

Research output: NLR › Presentation

Abstract

Metallization using complex metal inks has gained significant research interest due to its cost-effectiveness and ability to achieve performance comparable to traditional nanoparticle pastes. This study introduces the use of complex silver (Ag) inks applied via industrial screen-printing for silicon heterojunction (SHJ) solar cell metallization. The printed Ag lines exhibit a contact resistivity on SHJ tin-doped indium oxide (ITO) surfaces as low as approximately 0.2-12 mO cm2. Photoluminescence imaging reveals minimal surface passivation degradation (iVoc < 3.5 mV), while scanning electron microscopy (SEM) shows a denser structure compared to Ag layer from nanoparticle pastes. The printed Ag grid features thin (approximately 1 micrometer), continuous fingers approximately 100-120 micrometer wide, significantly thinner than conventional approximately 20-30 micrometer fingers produced with nanoparticle-based pastes. Double printing achieves SHJ device efficiencies exceeding 20%, the highest reported for industrial solar cell precursors using this technology. These findings highlight the potential of complex Ag inks as a sustainable alternative to particle-based pastes, reducing Ag consumption and processing temperatures without compromising efficiency.

Original language	American English
Number of pages	20
DOIs	https://doi.org/10.2172/3017377
State	Published - 2025

Publication series

Name	Presented at the 53rd IEEE Photovoltaic Specialists Conference (PVSC 53), 8-13 June 2025, Montreal, Canada

NLR Publication Number

NLR/PR-5K00-92867

Keywords

Cu/Ag
metallization
nanoparticle
screen printing
Si heterojunction

Access to Document

10.2172/3017377

https://www.nlr.gov/docs/fy26osti/92867.pdf

Cite this

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title = "Screen-Printed SHJ Solar Cells with Complex Silver Inks",

abstract = "Metallization using complex metal inks has gained significant research interest due to its cost-effectiveness and ability to achieve performance comparable to traditional nanoparticle pastes. This study introduces the use of complex silver (Ag) inks applied via industrial screen-printing for silicon heterojunction (SHJ) solar cell metallization. The printed Ag lines exhibit a contact resistivity on SHJ tin-doped indium oxide (ITO) surfaces as low as approximately 0.2-12 mO cm2. Photoluminescence imaging reveals minimal surface passivation degradation (iVoc < 3.5 mV), while scanning electron microscopy (SEM) shows a denser structure compared to Ag layer from nanoparticle pastes. The printed Ag grid features thin (approximately 1 micrometer), continuous fingers approximately 100-120 micrometer wide, significantly thinner than conventional approximately 20-30 micrometer fingers produced with nanoparticle-based pastes. Double printing achieves SHJ device efficiencies exceeding 20\%, the highest reported for industrial solar cell precursors using this technology. These findings highlight the potential of complex Ag inks as a sustainable alternative to particle-based pastes, reducing Ag consumption and processing temperatures without compromising efficiency.",

keywords = "Cu/Ag, metallization, nanoparticle, screen printing, Si heterojunction",

author = "Thien Truong and Matt Page and Sneh Sinha and Markus Kaupa and Mitchell Smith and Jennifer Selvidge and Harvey Guthrey and William Nemeth and San Theingi and Brett Walker and Myles Steiner and Paul Stradins and Melbs Lemieux and David Young",

year = "2025",

doi = "10.2172/3017377",

language = "American English",

series = "Presented at the 53rd IEEE Photovoltaic Specialists Conference (PVSC 53), 8-13 June 2025, Montreal, Canada",

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TY - GEN

T1 - Screen-Printed SHJ Solar Cells with Complex Silver Inks

AU - Truong, Thien

AU - Page, Matt

AU - Sinha, Sneh

AU - Kaupa, Markus

AU - Smith, Mitchell

AU - Selvidge, Jennifer

AU - Guthrey, Harvey

AU - Nemeth, William

AU - Theingi, San

AU - Walker, Brett

AU - Steiner, Myles

AU - Stradins, Paul

AU - Lemieux, Melbs

AU - Young, David

PY - 2025

Y1 - 2025

N2 - Metallization using complex metal inks has gained significant research interest due to its cost-effectiveness and ability to achieve performance comparable to traditional nanoparticle pastes. This study introduces the use of complex silver (Ag) inks applied via industrial screen-printing for silicon heterojunction (SHJ) solar cell metallization. The printed Ag lines exhibit a contact resistivity on SHJ tin-doped indium oxide (ITO) surfaces as low as approximately 0.2-12 mO cm2. Photoluminescence imaging reveals minimal surface passivation degradation (iVoc < 3.5 mV), while scanning electron microscopy (SEM) shows a denser structure compared to Ag layer from nanoparticle pastes. The printed Ag grid features thin (approximately 1 micrometer), continuous fingers approximately 100-120 micrometer wide, significantly thinner than conventional approximately 20-30 micrometer fingers produced with nanoparticle-based pastes. Double printing achieves SHJ device efficiencies exceeding 20%, the highest reported for industrial solar cell precursors using this technology. These findings highlight the potential of complex Ag inks as a sustainable alternative to particle-based pastes, reducing Ag consumption and processing temperatures without compromising efficiency.

AB - Metallization using complex metal inks has gained significant research interest due to its cost-effectiveness and ability to achieve performance comparable to traditional nanoparticle pastes. This study introduces the use of complex silver (Ag) inks applied via industrial screen-printing for silicon heterojunction (SHJ) solar cell metallization. The printed Ag lines exhibit a contact resistivity on SHJ tin-doped indium oxide (ITO) surfaces as low as approximately 0.2-12 mO cm2. Photoluminescence imaging reveals minimal surface passivation degradation (iVoc < 3.5 mV), while scanning electron microscopy (SEM) shows a denser structure compared to Ag layer from nanoparticle pastes. The printed Ag grid features thin (approximately 1 micrometer), continuous fingers approximately 100-120 micrometer wide, significantly thinner than conventional approximately 20-30 micrometer fingers produced with nanoparticle-based pastes. Double printing achieves SHJ device efficiencies exceeding 20%, the highest reported for industrial solar cell precursors using this technology. These findings highlight the potential of complex Ag inks as a sustainable alternative to particle-based pastes, reducing Ag consumption and processing temperatures without compromising efficiency.

KW - Cu/Ag

KW - metallization

KW - nanoparticle

KW - screen printing

KW - Si heterojunction

U2 - 10.2172/3017377

DO - 10.2172/3017377

M3 - Presentation

T3 - Presented at the 53rd IEEE Photovoltaic Specialists Conference (PVSC 53), 8-13 June 2025, Montreal, Canada

ER -

Screen-Printed SHJ Solar Cells with Complex Silver Inks

Abstract

Publication series

NLR Publication Number

Keywords

Access to Document

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Cite this