Recent Progress in Liquid Crystal‐Based Smart Windows: Materials, Structures, and Design

Shen, Wenbo; Li, Guoqiang

doi:10.1002/lpor.202200207

Cited by 38 publications

(27 citation statements)

References 244 publications

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“…Again, this review focuses on systems with the active materials being organics, generally avoiding papers in which the active elements are primarily inorganic, differentiating this work from other reviews on NIR control elements. [13][14][15][16][17][18][19][20] Organics provide several potential advantages over using inorganic materials, including organics do not interfere with, among others, radio signals, GPS, or cell phones, [21] nor do they corrode. In addition, processing of organic materials often requires lower temperatures and simpler processes than inorganic materials.…”

Section: Introductionmentioning

confidence: 99%

Recent advances in solar infrared light regulating smart windows based on organic materials

Sentjens

Kragt

Schenning

et al. 2023

Responsive Materials

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Windows serve the purpose of connecting room inhabitants with the outside environment, playing an important role in sustaining human health and well‐being. Windows also have a large impact on the lighting, heating, and cooling costs of indoor spaces. In this review, we discuss research over the past 5 years on “smart” windows based on organic materials designed to absorb, reflect, or otherwise utilize excess infrared radiation. In doing so, comfortable indoor temperatures can be managed throughout the year while maintaining as much as possible transparency to visible light, so additional energy is not required for artificial illumination. We discuss both static and dynamic infrared control windows, comparing some of their features and close with a discussion of where the field may be moving to allow these windows to make a commercial impact and reduce the need of heating and/or cooling systems for our indoor spaces.

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Section: Introductionmentioning

confidence: 99%

Recent advances in solar infrared light regulating smart windows based on organic materials

Sentjens

Kragt

Schenning

et al. 2023

Responsive Materials

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“…The results show that this phenomenon obeys the Bragg formula of crystal diffraction. The central wavelength of the reflection band is λ = n * P *cos𝜃, reflection bandwidth is Δ λ = Δ nP , where P , n , 𝜃, and Δ n denote the pitch, average refractive index of CLCs, incident angle of light with respect to the normal, and the birefringence of CLCs, respectively 7,8 . However, the usual Δ n is generally less than 0.3, and the corresponding Δλ is only less than 100 nm.…”

Section: Introductionmentioning

confidence: 99%

“…The central wavelength of the reflection band is λ = n*P*cosθ, reflection bandwidth is Δλ = ΔnP, where P, n, θ, and Δn denote the pitch, average refractive index of CLCs, incident angle of light with respect to the normal, and the birefringence of CLCs, respectively. 7,8 However, the usual Δn is generally less than 0.3, and the corresponding Δλ is only less than 100 nm. Therefore, in order to obtain extremely high birefringence cholesteric liquid crystal materials, we can only rely on synthesis, but this material is very difficult to synthesize, and in the ideal state, Δn is only 0.5.…”

Section: Introductionmentioning

confidence: 99%

Preparation of polymer‐stabilized cholesteric liquid crystal films capable of broadband reflection using a three‐layer system of self‐diffusion

Liu,

Zhang,

Cao

et al. 2023

Polymers for Advanced Techs

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Through a simple and effective method for preparing broadband reflective liquid crystal films, the advantages of the three‐layer system are expanded based on the two‐layer system. The cholesteric liquid crystals form a prepolymerized layer after semi‐curing. In the design of the top prepolymerization layer, there is less content of the chiral compound R5011, which results in the formation of cholesteric liquid crystal molecules with a larger pitch. Mainly by controlling the content of polymerizable monomers and UV‐absorbing dyes in cholesteric liquid crystals (CLCs), a polymer network with density gradient distribution suitable for substance diffusion is formed, and the oleophobic substrate on one side of the low‐density polymer network is more likely to be peeled off. In the design of the lowest prepolymerization layer, the content of R5011 is higher, which results in the formation of cholesteric liquid crystals with a larger pitch. One side substrate of two cholesteric liquid crystal cassettes is peeled off and merged into a new liquid crystal cassette whose left and right sides are stacked with septum pads (20 μm), and the nematic liquid crystals are poured into the middle layer to form a three‐layer integrated film. The polymer network of the polymer‐stabilized cholesteric liquid crystals (PSCLCs) itself in the bilayer was used as a diffusion channel. Chiral compounds and UV‐absorbing dyes were diffused from the cholesteric liquid crystal layer to the intermediate nematic liquid crystal layer by diffusion gradient method, resulting in liquid crystal films with arbitrary wavelength bands and ultrawide broadband reflection.

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“…Despite several emerging materials and technologies, possibilities to actively manipulate the ensuing optical properties in gel-like systems are still limited, rarely scalable, and often require high electrical energy input, which are widely recognized technological challenges. , Although high transmission and high haze properties have been achieved simultaneously in conventional gel-like materials developed from isotropic constituents, however, so far only in a static manner, − a suitable composition with optically anisotropic materials promises to enable orientation-dependent properties that can be regulated externally with weak stimuli like fields. In this direction, gel materials with combinations of an isotropic host network and anisotropic guest liquid or vice versa have been investigated, where one of the components is optically anisotropic.…”

Section: Introductionmentioning

confidence: 99%

“…The robust and reliable modulation of optical transparency in P-LC composite materials has shown potential impacts in diverse optical technologies ranging from smart windows ,, and information displays − to vision therapy, , optical security devices, and many more. , Yet, electrical switching in P-LC composites, including the commercially available PDLCs, suffers from the requirement of a high driving voltage, which is a key limiting factor for smart glass applications, especially in terms of power efficiency and both costs and safety considerations associated with high-voltage wiring of window units. These fundamental problems, along with the challenges of scalable, cost-effective manufacturing, have hindered the widespread adoption of P-LC materials for building-envelope technological applications. , Similar drawbacks also exist in alternate modes for controlling optical transmission with electrochromic materials and suspended particle devices . These methods provide a broad-band optical response covering UV to vis-NIR wavelengths but rely primarily on absorption mechanisms for optical tunability.…”

Section: Introductionmentioning

confidence: 99%

Low-Voltage Haze Tuning with Cellulose-Network Liquid Crystal Gels

Ghosh,

Abraham,

Smalyukh

2023

ACS Nano

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Being key components of the building envelope, glazing products with tunable optical properties are in great demand because of their potential for boosting energy efficiency and privacy features while enabling the main function of allowing natural light indoors. However, windows and skylights with electric switching of haze and transparency are rare and often require high voltages or electric currents, as well as not fully meet the stringent technical requirements for glazing applications. Here, by introducing a predesigned gel material we describe an approach dubbed “Haze-Switch” that involves low-voltage tuning of the haze coefficient in a broad range of 2–90% while maintaining high visible-range optical transmittance. The approach is based on a nanocellulose fiber gel network infiltrated by a nematic liquid crystal, which can be switched between polydomain and monodomain spatial patterns of optical axis via a dielectric coupling between the nematic domains and the applied external electric field. By utilizing a nanocellulose network of nanofibers ∼10 nm in diameter we achieve <10 V dielectric switching and <2% haze in the clear state, as needed for applications in window products. We characterize physical properties relevant to window and smart glass technologies, like the color rendering index, haze coefficient, and switching times, demonstrating that our material and envisaged products can meet the stringent requirements of the glass industry, including applications such as privacy windows, skylights, sunroofs, and daylighting.

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Recent Progress in Liquid Crystal‐Based Smart Windows: Materials, Structures, and Design

Cited by 38 publications

References 244 publications

Recent advances in solar infrared light regulating smart windows based on organic materials

Recent advances in solar infrared light regulating smart windows based on organic materials

Preparation of polymer‐stabilized cholesteric liquid crystal films capable of broadband reflection using a three‐layer system of self‐diffusion

Low-Voltage Haze Tuning with Cellulose-Network Liquid Crystal Gels

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