Photochromic Thermoelectric Smart Window for Season‐Adaptive Solar Heat and Daylight Management

Meng, Weihao; Kragt, Augustinus J.J.; Hu, Xiaowen; van der Burgt, Julia S.; Schenning, Albertus P.H.J.; Yue, Yuchen; Zhou, Guofu; Li, Laifeng; Wei, Ping; Zhao, Wenyu; Li, Yong; Wang, Jingxia; Jiang, Lei

doi:10.1002/adfm.202402494

Adv Funct Materials

2024

DOI: 10.1002/adfm.202402494

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Photochromic Thermoelectric Smart Window for Season‐Adaptive Solar Heat and Daylight Management

Weihao Meng,

Augustinus J.J. Kragt,

Xiaowen Hu

et al.

Abstract: Photochromic smart windows have drawn increasing attention as an approach to improve building energy efficiency and enhance indoor daylight comfort. However, existing photochromic smart windows still block sunlight from entering the room on sunny winter days, causing additional energy consumption for heating. Herein, a dual‐mode smart window is designed with decoupled photo and thermal functions by combining colorless Fe‐doped WO3 photochromic film with window rotation. Based on this, selective heating and coo… Show more

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Cited by 15 publications

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Advanced Design for Stimuli‐Reversible Chromic Wearables With Customizable Functionalities

Chen,

Yang,

Fang

et al. 2024

Advanced Materials

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Smart wearable devices with dynamically reversible color displays are crucial for the next generation of smart textiles, and promising for bio‐robots, adaptive camouflage, and visual health monitoring. The rapid advancement of technology brings out different categories that feature fundamentally different color‐reversing mechanisms, including thermochromic, mechanochromic, electrochromic, and photochromic smart wearables. Although some reviews have showcased relevant developments from unique perspectives, reviews focusing on the advanced design of flexible chromic wearable devices within each category have not been reported. In this review, the development history and recent progress in smart chromic wearables across each category are systematically examined. The design strategies for each chromic wearable device are outlined with a focus on functional materials, synthesis processes, and advanced applications. Furthermore, integrated devices based on dual‐stimuli and multi‐stimuli responsive chromics with customizable functionalities are summarized. Finally, challenges and perspectives on the future development of smart chromic wearables are proposed. Such a systematic summary will serve as a valuable insight for researchers in this field.

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Advanced Design for Stimuli‐Reversible Chromic Wearables With Customizable Functionalities

Chen,

Yang,

Fang

et al. 2024

Advanced Materials

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A Universal Strategy for Reversible Photochromism of Viologen Derivatives in Solutions

Guo,

Su,

Zong

et al. 2024

Advanced Optical Materials

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Viologens are important members of organic photochromic (PC) materials. However, the photochromism of the viologen derivatives in solutions, especially in water, can be hardly detected due to the restricted photo‐induced electron transfer (PET) caused by the solvation of counter anions and fast rapid back electron transfer upon oxidation by the dissolved oxygen. Herein, a universal strategy is successfully developed for reversible photochromism of viologen derivatives in various solvents by simply adding an electron donor triethylamine (TEA). Upon the formation of a charge transfer complex, PET process can smoothly occur, resulting in the formation of stable viologen radicals. The PC kinetic analysis reveals that a viologen derivative with narrower bandgap exhibits faster coloration process upon ultraviolet (UV) light irradiation. Moreover, incorporating 1‰ eq. of a conjugation‐extended viologen derivative as a photosensitizer significantly shortens the coloring time of a conventional viologen without affecting its bleached and colored states. Based on the PC properties of viologen derivatives, distinct patterns are realized in their aqueous solutions and pre‐soaked erasable papers upon UV light irradiation. Overall, the findings not only develop a universal strategy for reversible photochromism of viologen derivatives in various solvents but also open a new avenue for information storage and anticounterfeiting applications.

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Stimuli‐Responsive Smart Glass with Switchable Unidirectional Light Source for Enhanced Privacy/Indoor Illumination

Wu,

Selvaraj,

Tsai

et al. 2024

Advanced Optical Materials

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Light manipulation is in high demand in science and industry. Smart glasses enable dynamic light control for indoor illumination, privacy protection, automobiles, and displays. However, existing technologies often limit single‐functionality (simultaneous bidirectional transparency or opacity) and strongly inherent user preferences. Here, a novel class of stimuli‐responsive smart glass featuring a switchable unidirectional light source using 2,2‐dimethoxy‐2‐phenylacetophenone (DMPAP)‐doped twisted hybrid polymer network liquid crystals (TH‐PNLCs) with a linear polarizer is developed. These DMPAP‐doped TH‐PNLCs exhibit a blue‐shift in spectra under cross‐polarizer, enhanced twist angle, and increased light amplitude compared with undoped devices. When subjected to external electric stimuli and edge light, the device emits light bi‐directionally with different polarizations. As a proof of concept, placing a transmissive polarizer in front of the homogeneous alignment layer (Surface A) enables light absorption and scattering toward vertical alignment (Surface B), ensuring privacy by blocking visibility from Surface A while keeping Surface B visible. Replacing the transmissive linear polarizer with a reflective one enhances light scattering, boosting intensity from Surface B, making the device ideal for energy‐efficient indoor lighting. Featuring fast switching times and robust endurance, this stimuli‐responsive smart glass offers a pioneering solution for green buildings and automobiles with enhanced privacy and indoor illumination.

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Photochromic Thermoelectric Smart Window for Season‐Adaptive Solar Heat and Daylight Management

Cited by 15 publications

References 38 publications

Advanced Design for Stimuli‐Reversible Chromic Wearables With Customizable Functionalities

Advanced Design for Stimuli‐Reversible Chromic Wearables With Customizable Functionalities

A Universal Strategy for Reversible Photochromism of Viologen Derivatives in Solutions

Stimuli‐Responsive Smart Glass with Switchable Unidirectional Light Source for Enhanced Privacy/Indoor Illumination

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