Over 65% sunlight absorption in a 1 μm Si slab with hyperuniform texture
Over 65% sunlight absorption in a 1 μm Si slab with hyperuniform texture
Thin, flexible, and invisible solar cells will be a ubiquitous technology in the near future. Ultrathin crystalline silicon (c-Si) cells capitalize on the success of bulk silicon cells while being lightweight and mechanically flexible, but suffer from poor absorption and efficiency. Here we present a new family of surface texturing, based on correlated disordered hyperuniform patterns, capable of efficiently coupling the incident spectrum into the silicon slab optical modes. We experimentally demonstrate 66.5% solar light absorption in free-standing 1 μm c-Si layers by hyperuniform nanostructuring for the spectral range of 400 to 1050 nm. The absorption equivalent photocurrent derived from our measurements is 26.3 mA/cm2, which is far above the highest found in literature for Si of similar thickness. Considering state-of-the-art Si PV technologies, we estimate that the enhanced light trapping can result in a cell efficiency above 15%. The light absorption can potentially be increased up to 33.8 mA/cm2 by incorporating a back-reflector and improved antireflection, for which we estimate a photovoltaic efficiency above 21% for 1 μm thick Si cells.
1206-1217
Tavakoli, Nasim
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Spalding, Richard
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Lambertz, Alexander
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Koppejan, Pepijn
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Gkantzounis, Georgios
89ac79fa-7f76-4cf0-97d7-cbd84f02b940
Wan, Chenglong
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Röhrich, Ruslan
6151ace8-2fb8-4744-96ab-20f66c6c820c
Kontoleta, Evgenia
64513069-4d2d-4d6b-8758-be9d8033ddce
Koenderink, A. Femius
4b41f26e-c87b-45f0-b527-61e419e4f90d
Sapienza, Riccardo
dcecc61d-0d12-4cf1-aa98-a3cd940fe0ae
Florescu, Marian
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Alarcon-Llado, Esther
7bbc03c8-f430-4fa3-8fe6-593a30d92799
20 April 2022
Tavakoli, Nasim
aef866e9-ae4a-4c62-9d2f-d527149909d8
Spalding, Richard
018a8fd3-3e9f-42a5-b78e-5ef0f4b7b894
Lambertz, Alexander
b806a2b8-d000-44a8-a93c-355e25dc7ca1
Koppejan, Pepijn
d29a98c4-e692-40b6-93eb-854178fb01ba
Gkantzounis, Georgios
89ac79fa-7f76-4cf0-97d7-cbd84f02b940
Wan, Chenglong
1dc3bd51-08da-48de-9358-7bddb0d10c73
Röhrich, Ruslan
6151ace8-2fb8-4744-96ab-20f66c6c820c
Kontoleta, Evgenia
64513069-4d2d-4d6b-8758-be9d8033ddce
Koenderink, A. Femius
4b41f26e-c87b-45f0-b527-61e419e4f90d
Sapienza, Riccardo
dcecc61d-0d12-4cf1-aa98-a3cd940fe0ae
Florescu, Marian
14b7415d-9dc6-4ebe-a125-289e47648c65
Alarcon-Llado, Esther
7bbc03c8-f430-4fa3-8fe6-593a30d92799
Tavakoli, Nasim, Spalding, Richard, Lambertz, Alexander, Koppejan, Pepijn, Gkantzounis, Georgios, Wan, Chenglong, Röhrich, Ruslan, Kontoleta, Evgenia, Koenderink, A. Femius, Sapienza, Riccardo, Florescu, Marian and Alarcon-Llado, Esther
(2022)
Over 65% sunlight absorption in a 1 μm Si slab with hyperuniform texture.
ACS Photonics, 9 (4), .
(doi:10.1021/acsphotonics.1c01668).
Abstract
Thin, flexible, and invisible solar cells will be a ubiquitous technology in the near future. Ultrathin crystalline silicon (c-Si) cells capitalize on the success of bulk silicon cells while being lightweight and mechanically flexible, but suffer from poor absorption and efficiency. Here we present a new family of surface texturing, based on correlated disordered hyperuniform patterns, capable of efficiently coupling the incident spectrum into the silicon slab optical modes. We experimentally demonstrate 66.5% solar light absorption in free-standing 1 μm c-Si layers by hyperuniform nanostructuring for the spectral range of 400 to 1050 nm. The absorption equivalent photocurrent derived from our measurements is 26.3 mA/cm2, which is far above the highest found in literature for Si of similar thickness. Considering state-of-the-art Si PV technologies, we estimate that the enhanced light trapping can result in a cell efficiency above 15%. The light absorption can potentially be increased up to 33.8 mA/cm2 by incorporating a back-reflector and improved antireflection, for which we estimate a photovoltaic efficiency above 21% for 1 μm thick Si cells.
Text
tavakoli-et-al-2022-over-65-sunlight-absorption-in-a-1-μm-si-slab-with-hyperuniform-texture
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e-pub ahead of print date: 22 March 2022
Published date: 20 April 2022
Identifiers
Local EPrints ID: 502840
URI: http://eprints.soton.ac.uk/id/eprint/502840
ISSN: 2330-4022
PURE UUID: 9cc381c1-106f-462c-a69a-b197fa70a87c
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Date deposited: 09 Jul 2025 16:36
Last modified: 22 Aug 2025 02:46
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Contributors
Author:
Nasim Tavakoli
Author:
Richard Spalding
Author:
Alexander Lambertz
Author:
Pepijn Koppejan
Author:
Georgios Gkantzounis
Author:
Chenglong Wan
Author:
Ruslan Röhrich
Author:
Evgenia Kontoleta
Author:
A. Femius Koenderink
Author:
Riccardo Sapienza
Author:
Marian Florescu
Author:
Esther Alarcon-Llado
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