We herein propose a proof of concept of a full dual-band electrochromic (EC) device able to selectively modulate solar light between 300 and 1600 nm. Dual-band control was achieved by exploiting the complementarity and cooperation of two earth-abundant and nontoxic transition metal oxide nanocrystalline materials able to absorb two different spectral regions when electrochemically charged. The active materials were obtained through a microwave-based synthetic protocol able to produce massive amounts of ligand-free water-soluble TiO@WO colloidal heterostructured nanocrystals. The inorganic heterostructures were deposited via a spray-coating airbrushing method. Graphene was adopted as a near-infrared (NIR) transparent material for the realization of conductive substrates. The nano-dimensions and stable solubility of active materials during the deposition process endorse the development of scattering-free nanostructured electrodes and high device transparency under open-circuit conditions, respectively. The spectro-electrochemical properties of the as-made nanostructured electrodes were evaluated in relation to pure WO and TiO single nanomaterials and a blend of these. The heterostructured architecture ensures a lower optical haze (around 8% of total radiation) as against the blend, contributing to improving the overall EC performance. The TiO@WO-based device shows 67% NIR shielding while preserving 60% of visible (VIS) transparency under cool-mode conditions and 89% screening of VIS and NIR radiation under the dark mode. These results represent an important step forward in the development of scalable dual-band EC devices.

Visible Light-Near-Infrared Dual-Band Electrochromic Device

Pugliese Marco;Scarfiello Riccardo;Bianco Giuseppe Valerio;Mariano Fabrizio;Maggiore Antonio;Carbone Luigi;Maiorano Vincenzo
2023

Abstract

We herein propose a proof of concept of a full dual-band electrochromic (EC) device able to selectively modulate solar light between 300 and 1600 nm. Dual-band control was achieved by exploiting the complementarity and cooperation of two earth-abundant and nontoxic transition metal oxide nanocrystalline materials able to absorb two different spectral regions when electrochemically charged. The active materials were obtained through a microwave-based synthetic protocol able to produce massive amounts of ligand-free water-soluble TiO@WO colloidal heterostructured nanocrystals. The inorganic heterostructures were deposited via a spray-coating airbrushing method. Graphene was adopted as a near-infrared (NIR) transparent material for the realization of conductive substrates. The nano-dimensions and stable solubility of active materials during the deposition process endorse the development of scattering-free nanostructured electrodes and high device transparency under open-circuit conditions, respectively. The spectro-electrochemical properties of the as-made nanostructured electrodes were evaluated in relation to pure WO and TiO single nanomaterials and a blend of these. The heterostructured architecture ensures a lower optical haze (around 8% of total radiation) as against the blend, contributing to improving the overall EC performance. The TiO@WO-based device shows 67% NIR shielding while preserving 60% of visible (VIS) transparency under cool-mode conditions and 89% screening of VIS and NIR radiation under the dark mode. These results represent an important step forward in the development of scalable dual-band EC devices.
2023
dual-band modulation
electrochromic device
graphene electrode
heterostructured TiO @WO nanocrystals 2 3-x
near-infrared radiation
spray coating
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/20.500.14243/452443
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