Passive radiative cooling of solar cells by low-cost and scalable metamaterials: physical simulation and efficiency limits

Matteo Cagnoni; Alberto Tibaldi; Pietro Testa; Jorge S. Dolado; Federica Cappelluti

doi:10.1117/12.2607489

Passive radiative cooling of solar cells by low-cost and scalable metamaterials: physical simulation and efficiency limits

Matteo Cagnoni^*
, Alberto Tibaldi
, Pietro Testa
, Jorge S. Dolado
, Federica Cappelluti

^*Autor correspondiente de este trabajo

Polytechnic University of Turin
CSIC UPV Centro de Fisica de Materials CFM
Donostia International Physics Center

Producción científica: Capítulo del libro/informe/acta de congreso › Contribución a la conferencia › revisión exhaustiva

6 Citas (Scopus)

Resumen

Radiative cooling is an attractive concept for future sustainable energy strategies, as it might enable passive cooling of buildings and photovoltaic systems, hence facilitating energy savings by boosting performance and lifespan. The key idea is the adoption of materials that strongly emit thermal radiation in the atmosphere transparency window (wavelengths between 8 and 13 μm) as cooling layers. Significant progress in the field of metamaterials has enabled the realization of dielectric photonic structures with properties matching radiative cooling requirements and capable of going below ambient temperature. However, these structures are rather expensive and appear unsuitable for today's large-scale manufacturing. In the present work, we have studied radiative cooling applied to Shockley-Queisser solar cells by exploring alternative materials, namely cementitious phases, which exhibit the required properties while being low-cost and scalable. We have determined their emission behavior by electromagnetic simulations and estimated the corresponding solar cell operating temperature by means of a detailed-balance model. The results have been benchmarked against the current state-of-the-art and hint at the possible realization of a new class of radiative coolers based on cheap and scalable cementitious materials.

Idioma original	Inglés
Título de la publicación alojada	Physics, Simulation, and Photonic Engineering of Photovoltaic Devices XI
Editores	Alexandre Freundlich, Stephane Collin, Karin Hinzer
Editorial	SPIE
ISBN (versión digital)	9781510648630
DOI	https://doi.org/10.1117/12.2607489
Estado	Publicada - 2022
Publicado de forma externa	Sí
Evento	Physics, Simulation, and Photonic Engineering of Photovoltaic Devices XI 2022 - Virtual, Online Duración: 20 feb 2022 → 24 feb 2022

Serie de la publicación

Nombre	Proceedings of SPIE - The International Society for Optical Engineering
Volumen	11996
ISSN (versión impresa)	0277-786X
ISSN (versión digital)	1996-756X

Conferencia

Conferencia	Physics, Simulation, and Photonic Engineering of Photovoltaic Devices XI 2022
Ciudad	Virtual, Online
Período	20/02/22 → 24/02/22

ODS de las Naciones Unidas

Este resultado contribuye a los siguientes Objetivos de Desarrollo Sostenible

ODS 7: Energía asequible y no contaminante
ODS 9: Industria, innovación e infraestructura

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Cagnoni, M., Tibaldi, A., Testa, P., Dolado, J. S., & Cappelluti, F. (2022). Passive radiative cooling of solar cells by low-cost and scalable metamaterials: physical simulation and efficiency limits. En A. Freundlich, S. Collin, & K. Hinzer (Eds.), Physics, Simulation, and Photonic Engineering of Photovoltaic Devices XI Artículo 1199606 (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 11996). SPIE. https://doi.org/10.1117/12.2607489

Cagnoni, Matteo ; Tibaldi, Alberto ; Testa, Pietro et al. / Passive radiative cooling of solar cells by low-cost and scalable metamaterials : physical simulation and efficiency limits. Physics, Simulation, and Photonic Engineering of Photovoltaic Devices XI. editor / Alexandre Freundlich ; Stephane Collin ; Karin Hinzer. SPIE, 2022. (Proceedings of SPIE - The International Society for Optical Engineering).

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abstract = "Radiative cooling is an attractive concept for future sustainable energy strategies, as it might enable passive cooling of buildings and photovoltaic systems, hence facilitating energy savings by boosting performance and lifespan. The key idea is the adoption of materials that strongly emit thermal radiation in the atmosphere transparency window (wavelengths between 8 and 13 μm) as cooling layers. Significant progress in the field of metamaterials has enabled the realization of dielectric photonic structures with properties matching radiative cooling requirements and capable of going below ambient temperature. However, these structures are rather expensive and appear unsuitable for today's large-scale manufacturing. In the present work, we have studied radiative cooling applied to Shockley-Queisser solar cells by exploring alternative materials, namely cementitious phases, which exhibit the required properties while being low-cost and scalable. We have determined their emission behavior by electromagnetic simulations and estimated the corresponding solar cell operating temperature by means of a detailed-balance model. The results have been benchmarked against the current state-of-the-art and hint at the possible realization of a new class of radiative coolers based on cheap and scalable cementitious materials.",

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Cagnoni, M, Tibaldi, A, Testa, P, Dolado, JS & Cappelluti, F 2022, Passive radiative cooling of solar cells by low-cost and scalable metamaterials: physical simulation and efficiency limits. En A Freundlich, S Collin & K Hinzer (eds.), Physics, Simulation, and Photonic Engineering of Photovoltaic Devices XI., 1199606, Proceedings of SPIE - The International Society for Optical Engineering, vol. 11996, SPIE, Physics, Simulation, and Photonic Engineering of Photovoltaic Devices XI 2022, Virtual, Online, 20/02/22. https://doi.org/10.1117/12.2607489

Passive radiative cooling of solar cells by low-cost and scalable metamaterials: physical simulation and efficiency limits. / Cagnoni, Matteo; Tibaldi, Alberto; Testa, Pietro et al.
Physics, Simulation, and Photonic Engineering of Photovoltaic Devices XI. ed. / Alexandre Freundlich; Stephane Collin; Karin Hinzer. SPIE, 2022. 1199606 (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 11996).

Producción científica: Capítulo del libro/informe/acta de congreso › Contribución a la conferencia › revisión exhaustiva

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T2 - Physics, Simulation, and Photonic Engineering of Photovoltaic Devices XI 2022

AU - Cagnoni, Matteo

AU - Tibaldi, Alberto

AU - Testa, Pietro

AU - Dolado, Jorge S.

AU - Cappelluti, Federica

PY - 2022

Y1 - 2022

N2 - Radiative cooling is an attractive concept for future sustainable energy strategies, as it might enable passive cooling of buildings and photovoltaic systems, hence facilitating energy savings by boosting performance and lifespan. The key idea is the adoption of materials that strongly emit thermal radiation in the atmosphere transparency window (wavelengths between 8 and 13 μm) as cooling layers. Significant progress in the field of metamaterials has enabled the realization of dielectric photonic structures with properties matching radiative cooling requirements and capable of going below ambient temperature. However, these structures are rather expensive and appear unsuitable for today's large-scale manufacturing. In the present work, we have studied radiative cooling applied to Shockley-Queisser solar cells by exploring alternative materials, namely cementitious phases, which exhibit the required properties while being low-cost and scalable. We have determined their emission behavior by electromagnetic simulations and estimated the corresponding solar cell operating temperature by means of a detailed-balance model. The results have been benchmarked against the current state-of-the-art and hint at the possible realization of a new class of radiative coolers based on cheap and scalable cementitious materials.

AB - Radiative cooling is an attractive concept for future sustainable energy strategies, as it might enable passive cooling of buildings and photovoltaic systems, hence facilitating energy savings by boosting performance and lifespan. The key idea is the adoption of materials that strongly emit thermal radiation in the atmosphere transparency window (wavelengths between 8 and 13 μm) as cooling layers. Significant progress in the field of metamaterials has enabled the realization of dielectric photonic structures with properties matching radiative cooling requirements and capable of going below ambient temperature. However, these structures are rather expensive and appear unsuitable for today's large-scale manufacturing. In the present work, we have studied radiative cooling applied to Shockley-Queisser solar cells by exploring alternative materials, namely cementitious phases, which exhibit the required properties while being low-cost and scalable. We have determined their emission behavior by electromagnetic simulations and estimated the corresponding solar cell operating temperature by means of a detailed-balance model. The results have been benchmarked against the current state-of-the-art and hint at the possible realization of a new class of radiative coolers based on cheap and scalable cementitious materials.

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KW - metamaterials

KW - radiative cooling

KW - solar cells

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M3 - Conference contribution

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BT - Physics, Simulation, and Photonic Engineering of Photovoltaic Devices XI

A2 - Freundlich, Alexandre

A2 - Collin, Stephane

A2 - Hinzer, Karin

PB - SPIE

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ER -

Cagnoni M, Tibaldi A, Testa P, Dolado JS, Cappelluti F. Passive radiative cooling of solar cells by low-cost and scalable metamaterials: physical simulation and efficiency limits. En Freundlich A, Collin S, Hinzer K, editores, Physics, Simulation, and Photonic Engineering of Photovoltaic Devices XI. SPIE. 2022. 1199606. (Proceedings of SPIE - The International Society for Optical Engineering). doi: 10.1117/12.2607489

Passive radiative cooling of solar cells by low-cost and scalable metamaterials: physical simulation and efficiency limits

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