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Self-powered switchable glazing based on nematic liquid crystals and organic photovoltaic layers for smart windows applications

Self-powered switchable glazing based on nematic liquid crystals and organic photovoltaic layers for smart windows applications
Self-powered switchable glazing based on nematic liquid crystals and organic photovoltaic layers for smart windows applications
Dynamic windows allow monitoring of in-door solar radiation and thus improve user comfort and energy efficiency in buildings and vehicles. Existing technologies are, however, hampered by limitations in switching speed, energy efficiency, user control, or production costs. Here, we introduce a new concept for self-powered switchable glazing that combines a nematic liquid crystal, as an electro-optic active layer, with an organic photovoltaic material. The latter aligns the liquid crystal molecules and generates, under illumination, an electric field that changes the molecular orientation and thereby the device transmittance in the visible and near-infrared region. Small-area devices can be switched from clear to dark in hundreds of milliseconds without an external power supply. The drop in transmittance can be adjusted using a variable resistor and is shown to be reversible and stable for more than 5 h. First solution-processed large-area (15 cm2) devices are presented, and prospects for smart window applications are discussed.
1944-8252
4267–4274
Fall, Sadiara
eced6f7f-12da-4219-8ed8-7f151fe6179d
Wang, Jing
e4e9a1d5-fa50-4ae5-a28a-4491280b5dad
Regrettier, Thomas
3cda19a0-cb48-479d-883c-4dedb70f249a
Brouckaert, Nicolas
3a5fc4fe-1d30-4102-9edd-c15d134a5c4b
Ibraikulov, Olzhas A.
2db59876-2dd2-4d7c-a87d-44a7f7453809
Leclerc, Nicolas
9120d1da-d2e6-4719-aa67-b3228d5e731b
Lin, Yaochen
6e75108c-a350-481b-82b3-c14051c6c3ce
Elhaj, Mohammed Ibn
17f532e9-315f-4b83-ad40-9ace83e101fe
Komitov, Lachezar
d9f35cb9-9c3a-4f36-98df-76f2a27f1f98
Lévêque, Patrick
c0ddbab9-cdcd-4a00-83b8-55a3fe530f3b
Zhong, Yuhan
4f191e72-7454-4211-8d4c-8cf5e12e8a52
Brinkmann, Martin
1bb47df8-d610-4fb5-88b1-5005a91dc049
Kaczmarek, Malgosia
408ec59b-8dba-41c1-89d0-af846d1bf327
Heiser, Thomas
7ea3dce3-9bd4-4089-a3cf-8993d7f2a273
Fall, Sadiara
eced6f7f-12da-4219-8ed8-7f151fe6179d
Wang, Jing
e4e9a1d5-fa50-4ae5-a28a-4491280b5dad
Regrettier, Thomas
3cda19a0-cb48-479d-883c-4dedb70f249a
Brouckaert, Nicolas
3a5fc4fe-1d30-4102-9edd-c15d134a5c4b
Ibraikulov, Olzhas A.
2db59876-2dd2-4d7c-a87d-44a7f7453809
Leclerc, Nicolas
9120d1da-d2e6-4719-aa67-b3228d5e731b
Lin, Yaochen
6e75108c-a350-481b-82b3-c14051c6c3ce
Elhaj, Mohammed Ibn
17f532e9-315f-4b83-ad40-9ace83e101fe
Komitov, Lachezar
d9f35cb9-9c3a-4f36-98df-76f2a27f1f98
Lévêque, Patrick
c0ddbab9-cdcd-4a00-83b8-55a3fe530f3b
Zhong, Yuhan
4f191e72-7454-4211-8d4c-8cf5e12e8a52
Brinkmann, Martin
1bb47df8-d610-4fb5-88b1-5005a91dc049
Kaczmarek, Malgosia
408ec59b-8dba-41c1-89d0-af846d1bf327
Heiser, Thomas
7ea3dce3-9bd4-4089-a3cf-8993d7f2a273

Fall, Sadiara, Wang, Jing, Regrettier, Thomas, Brouckaert, Nicolas, Ibraikulov, Olzhas A., Leclerc, Nicolas, Lin, Yaochen, Elhaj, Mohammed Ibn, Komitov, Lachezar, Lévêque, Patrick, Zhong, Yuhan, Brinkmann, Martin, Kaczmarek, Malgosia and Heiser, Thomas (2023) Self-powered switchable glazing based on nematic liquid crystals and organic photovoltaic layers for smart windows applications. ACS Applied Materials and Interfaces, 15 (3), 4267–4274. (doi:10.1021/acsami.2c21727).

Record type: Article

Abstract

Dynamic windows allow monitoring of in-door solar radiation and thus improve user comfort and energy efficiency in buildings and vehicles. Existing technologies are, however, hampered by limitations in switching speed, energy efficiency, user control, or production costs. Here, we introduce a new concept for self-powered switchable glazing that combines a nematic liquid crystal, as an electro-optic active layer, with an organic photovoltaic material. The latter aligns the liquid crystal molecules and generates, under illumination, an electric field that changes the molecular orientation and thereby the device transmittance in the visible and near-infrared region. Small-area devices can be switched from clear to dark in hundreds of milliseconds without an external power supply. The drop in transmittance can be adjusted using a variable resistor and is shown to be reversible and stable for more than 5 h. First solution-processed large-area (15 cm2) devices are presented, and prospects for smart window applications are discussed.

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More information

Accepted/In Press date: 26 December 2022
e-pub ahead of print date: 11 January 2023
Published date: 25 January 2023

Identifiers

Local EPrints ID: 491521
URI: http://eprints.soton.ac.uk/id/eprint/491521
ISSN: 1944-8252
PURE UUID: 3847a786-3490-41ca-bdec-f6dbc63e5953

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Date deposited: 25 Jun 2024 17:00
Last modified: 11 Nov 2024 18:05

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Contributors

Author: Sadiara Fall
Author: Jing Wang
Author: Thomas Regrettier
Author: Nicolas Brouckaert
Author: Olzhas A. Ibraikulov
Author: Nicolas Leclerc
Author: Yaochen Lin
Author: Mohammed Ibn Elhaj
Author: Lachezar Komitov
Author: Patrick Lévêque
Author: Yuhan Zhong
Author: Martin Brinkmann
Author: Thomas Heiser

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