Hyperuniform disordered phononic structures (Conference Presentation)
Hyperuniform disordered phononic structures (Conference Presentation)
Introducing thin, light-weight and high efficiency photovoltaics will make solar cells more suitable to be integrated in urban landscapes or even small gadgets and would largely contribute to solving the global warming threat that we are facing today. Stacking of solar cells with different characteristic bandgaps is the most common strategy to surpass the Shockley-Queisser efficiency limit, but such tandem devices are typically heavy weight, rigid and costly. Thinning down of absorber materials is a good strategy to overcome these restrictions. However, nano- and micro-meter thicknesses come down to the expense of light absorption. An effective approach to tackle the absorption problem in thin materials is nanopatterning the absorbing layer. In this work we introduce hyperuniform designs as an effective way to control scattered light into particular range of angles (revealed as a ring in k-space of the reflected/transmitted light), with the aim to efficiently trap light in μm-thick Silicon (Si) cells. We first consider the –theoretical and experimental- case of a single Si solar cell, and thanks to an optimization algorithm, we show the highest light absorption in 1 μm-thick Si film to date. We also compare different designs for best anti-reflection effect on top of light trapping and characterize the increased absorption in photoelectrochemical devices. Second, we incorporate a similar light trapping strategy in a tandem solar cell, by using a periodic GaAs nanowire array as a top cell. We introduce two waveguiding effects in GaAs NW-Si thin film architectures to explain the 4-fold light absorption in the Si ultrathin bottom cell for tailored geometries of the NW array. These results represent significant light trapping scheme that is obtained “for free” when using a nanostructured top cell.
Florescu, Marian
14b7415d-9dc6-4ebe-a125-289e47648c65
Gkantzounis, George
20e2fc19-dad3-41fd-af93-8b57db57e222
Amoah, Timothy
c6334087-1222-495f-97b3-f3a645515076
Adibi, Ali
4c466a4b-4165-42fc-826d-1d5aa43e4da7
Lin, Shawn-Yu
e089c451-41e0-49b2-b735-481564ff2f9f
Scherer, Axel
81576199-3c5f-42e4-8924-93a1be83d670
14 March 2018
Florescu, Marian
14b7415d-9dc6-4ebe-a125-289e47648c65
Gkantzounis, George
20e2fc19-dad3-41fd-af93-8b57db57e222
Amoah, Timothy
c6334087-1222-495f-97b3-f3a645515076
Adibi, Ali
4c466a4b-4165-42fc-826d-1d5aa43e4da7
Lin, Shawn-Yu
e089c451-41e0-49b2-b735-481564ff2f9f
Scherer, Axel
81576199-3c5f-42e4-8924-93a1be83d670
Florescu, Marian, Gkantzounis, George and Amoah, Timothy
(2018)
Hyperuniform disordered phononic structures (Conference Presentation).
Adibi, Ali, Lin, Shawn-Yu and Scherer, Axel
(eds.)
In Proceedings Photonics for Solar Energy Systems VIII.
vol. 11366
(doi:10.1117/12.2290072).
Record type:
Conference or Workshop Item
(Paper)
Abstract
Introducing thin, light-weight and high efficiency photovoltaics will make solar cells more suitable to be integrated in urban landscapes or even small gadgets and would largely contribute to solving the global warming threat that we are facing today. Stacking of solar cells with different characteristic bandgaps is the most common strategy to surpass the Shockley-Queisser efficiency limit, but such tandem devices are typically heavy weight, rigid and costly. Thinning down of absorber materials is a good strategy to overcome these restrictions. However, nano- and micro-meter thicknesses come down to the expense of light absorption. An effective approach to tackle the absorption problem in thin materials is nanopatterning the absorbing layer. In this work we introduce hyperuniform designs as an effective way to control scattered light into particular range of angles (revealed as a ring in k-space of the reflected/transmitted light), with the aim to efficiently trap light in μm-thick Silicon (Si) cells. We first consider the –theoretical and experimental- case of a single Si solar cell, and thanks to an optimization algorithm, we show the highest light absorption in 1 μm-thick Si film to date. We also compare different designs for best anti-reflection effect on top of light trapping and characterize the increased absorption in photoelectrochemical devices. Second, we incorporate a similar light trapping strategy in a tandem solar cell, by using a periodic GaAs nanowire array as a top cell. We introduce two waveguiding effects in GaAs NW-Si thin film architectures to explain the 4-fold light absorption in the Si ultrathin bottom cell for tailored geometries of the NW array. These results represent significant light trapping scheme that is obtained “for free” when using a nanostructured top cell.
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Published date: 14 March 2018
Venue - Dates:
SPIE Photonics Europe 2020, , Strasbourg, France, 2020-03-29 - 2020-04-02
Identifiers
Local EPrints ID: 501759
URI: http://eprints.soton.ac.uk/id/eprint/501759
PURE UUID: 3160e87b-79e3-47f1-8628-be21171c155a
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Date deposited: 09 Jun 2025 18:05
Last modified: 22 Aug 2025 02:46
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Contributors
Author:
Marian Florescu
Author:
George Gkantzounis
Author:
Timothy Amoah
Editor:
Ali Adibi
Editor:
Shawn-Yu Lin
Editor:
Axel Scherer
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