Luminescent solar concentrators (LSCs) are spectral conversion devices offering interesting opportunities for the integration of photovoltaics into the built environment and portable systems. The Forster-resonance energy transfer (FRET) process can boost the optical response of LSCs by reducing energy losses typically associated to non-radiative processes occurring within the device under operation. In this work, a new class of FRET-based thin-film LSC devices is presented, in which the synthetic versatility of linear polyurethanes (PU) is exploited to control the photophysical properties and the device performance of the resulting LSCs. A series of luminescent linear PUs are synthesized in the presence of two novel bis-hydroxyl-functionalized luminophores of suitable optical properties, used as chain extenders during the step-growth polyaddition reaction for the formation of the linear macromolecular network. By synthetically tuning their composition, the obtained luminescent PUs can achieve a high energy transfer efficiency (approximate to 90%) between the covalently linked luminophores. The corresponding LSC devices exhibit excellent photonic response, with external and internal photon efficiencies as high as approximate to 4% and approximate to 37%, respectively. Furthermore, their optimized power conversion efficiency combined with their enhanced average visible-light transmittance highlight their suitability for potential use as transparent solar energy devices.The first demonstration of thin-film luminescent solar concentrators based on efficient energy transfer between luminescent moieties covalently incorporated in polyurethane systems is presented in this work. Excellent photonic and device response is demonstrated by tailoring polymer composition, yielding an efficient donor-acceptor energy transfer process. These materials show promise for application in the field of transparent photovoltaics for building integration. image
Semi‐Transparent Luminescent Solar Concentrators Based on Intramolecular Energy Transfer in Polyurethane Matrices
Tatsi, Elisavet;Turri, Stefano;Griffini, Gianmarco
2024-01-01
Abstract
Luminescent solar concentrators (LSCs) are spectral conversion devices offering interesting opportunities for the integration of photovoltaics into the built environment and portable systems. The Forster-resonance energy transfer (FRET) process can boost the optical response of LSCs by reducing energy losses typically associated to non-radiative processes occurring within the device under operation. In this work, a new class of FRET-based thin-film LSC devices is presented, in which the synthetic versatility of linear polyurethanes (PU) is exploited to control the photophysical properties and the device performance of the resulting LSCs. A series of luminescent linear PUs are synthesized in the presence of two novel bis-hydroxyl-functionalized luminophores of suitable optical properties, used as chain extenders during the step-growth polyaddition reaction for the formation of the linear macromolecular network. By synthetically tuning their composition, the obtained luminescent PUs can achieve a high energy transfer efficiency (approximate to 90%) between the covalently linked luminophores. The corresponding LSC devices exhibit excellent photonic response, with external and internal photon efficiencies as high as approximate to 4% and approximate to 37%, respectively. Furthermore, their optimized power conversion efficiency combined with their enhanced average visible-light transmittance highlight their suitability for potential use as transparent solar energy devices.The first demonstration of thin-film luminescent solar concentrators based on efficient energy transfer between luminescent moieties covalently incorporated in polyurethane systems is presented in this work. Excellent photonic and device response is demonstrated by tailoring polymer composition, yielding an efficient donor-acceptor energy transfer process. These materials show promise for application in the field of transparent photovoltaics for building integration. imageFile | Dimensione | Formato | |
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