Tailoring Broad-Band-Absorbed Thermoplasmonic 1D Nanochains for Smart Windows with Adaptive Solar Modulation

Guo, Min; Yu, Qiaoqi; Wang, Xingchi; Xu, Wanxuan; Wei, Yi; Ma, Ying; Yu, Jianyong; Ding, Bin

doi:10.1021/acsami.0c21584

Cited by 36 publications

(29 citation statements)

References 56 publications

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“…T lum (380–780 nm), T solar (300–2500 nm) and D T solar could be determined by the following equations:

\begin{matrix} T_{lum, solar} = \frac{\int ϕ_{lum, solar} (λ) T (λ) d (λ)}{\int ϕ_{lum, solar} (λ) d (λ)} \end{matrix}

\begin{matrix} Δ T_{lum, solar} = T_{lum, solar} (T) - T_{lum, solar} (20^{\circ} normalC) \end{matrix}

where ϕ lum (λ) is the standard luminous efficiency function for photopic vision, [ 34 ] ϕ solar (λ) is the solar irradiance spectrum for air mass 1.5 (AM1.5, corresponding to the sun standing 37° above the horizon), [ 35 ] T (λ) is the measured spectral transmittance, and T is the testing temperature. Compared with the recently reported results of the most studied inorganic VO 2 thermochromic coatings [ 10,36–38 ] and other hydrogel‐based smart windows, [ 17,39–42 ] an unprecedented combination of high T lum (99.05%) and D T solar (33.42%) could be achieved by applying the Gel‐0.8‐NaCl hydrogel (Table S1, Supporting Information). It is notable that the T lum exceeds all the literature data, while the moderate D T solar value can be attributed to the fact that other smart window technologies allow the full regions of the solar irradiation to through and our hydrogels will block infrared spectra.…”

Section: Resultsmentioning

confidence: 79%

Thermochromic Hydrogels with Dynamic Solar Modulation and Regulatable Critical Response Temperature for Energy‐Saving Smart Windows

Xia

Chen

et al. 2021

Adv Funct Materials

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Conventional buildings consume about 40% of global energy, smart window technologies have been developed for sunlight modulation and energy management. Most current smart windows change from transparent to opaque as the temperature rises, which is detrimental to indoor lighting at daytime or privacy protection at night. In this work, a versatile thermochromic hydrogel system by introducing sodium dodecyl sulfate (SDS) micelles into a crosslinked copolymer of hydrophilic acrylamide and hydrophobic stearyl methacrylate (C18) is developed. The liquid precursor solution can be encapsulated within two glass panels and in situ gelated to prepared smart windows, which showed excellent solar modulation ability (Tlum = 99.05%, DTsolar = 33.42%), dual responsiveness (thermal and pH) and tunable phase transition temperature (20–50 °C). Moreover, this design selectively blocks infrared light, while allowing ultraviolet and visible light through at daytime, which is beneficial for indoor illumination and heat insulation. When temperature drops at night, C18 units aggregate within SDS micelles to increase their dimensions, causing enhanced light blocking properties (opaque) to protect the customers’ privacy. The as‐prepared hydrogel‐based smart windows present a facile strategy to meet the stringent requirements of high transparency, excellent solar modulation ability, easy to fabricate and mechanical flexibility, holding great promise for the next‐generation energy‐saving buildings.

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“…T lum (380–780 nm), T solar (300–2500 nm) and D T solar could be determined by the following equations:

\begin{matrix} T_{lum, solar} = \frac{\int ϕ_{lum, solar} (λ) T (λ) d (λ)}{\int ϕ_{lum, solar} (λ) d (λ)} \end{matrix}

\begin{matrix} Δ T_{lum, solar} = T_{lum, solar} (T) - T_{lum, solar} (20^{\circ} normalC) \end{matrix}

Section: Resultsmentioning

confidence: 79%

Thermochromic Hydrogels with Dynamic Solar Modulation and Regulatable Critical Response Temperature for Energy‐Saving Smart Windows

Xia

Chen

et al. 2021

Adv Funct Materials

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“…Other thermosensitive materials include poly(N‐vinylcaprolactam), [114] methyl‐ or hydroxypropyl cellulose, [115–118] and polyampholyte hydrogels [119] . It has been reported that a faster thermal response can be achieved in these polymers by incorporating Au nanoparticles or Au nanoparticle clusters (Figures 1d–f) [120] . Owing to the LSPR characteristics of Au nanoparticles and their clusters at visible and near‐infrared frequencies, they are able to absorb and scatter the light with different proportionality according to their geometries [121] .…”

Section: Thermochromic Smart Windowsmentioning

confidence: 99%

“…(e,f) Time‐course change in the window temperatures (e) and indoor temperatures (f) of the bare glass, PNiPAAM‐based smart window, and PNiPAAM‐based smart window containing Au nanoparticle clusters under the irradiation of simulated solar lights. Reproduced with permission [120] . Copyright 2021, American Chemical Society.…”

Section: Thermochromic Smart Windowsmentioning

confidence: 99%

“…Reproduced with permission. [120] Copyright 2021, American Chemical Society. (g) A schematic for the working principle of the smart windows composed of PNiPAAM-based hydrogel and antimony-tin oxide (ATO) nanoparticles.…”

Section: Thermochromic Smart Windowsmentioning

confidence: 99%

“…faster thermal response can be achieved in these polymers by incorporating Au nanoparticles or Au nanoparticle clusters (Figures 1d-f). [120] Owing to the LSPR characteristics of Au nanoparticles and their clusters at visible and near-infrared frequencies, they are able to absorb and scatter the light with different proportionality according to their geometries. [121] If the nanoparticles have a high absorption ratio or absorption crosssection, then the absorbed light can be converted to heat, which in turn increases the overall temperature of the window.…”

Section: Thermochromic Smart Windowsmentioning

confidence: 99%

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Multi‐stimuli‐responsive and Multi‐functional Smart Windows

et al. 2022

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Smart windows can change their optical characteristics according to environmental conditions or external stimuli (such as heat and electricity). They are manufactured by considering building characteristics, regional climate, energy policies, and indoor air conditions. Their key optical properties have been improved by developing novel materials, fabrication methods, and designs. The optical properties can be further improved by developing multi‐stimuli‐responsive smart window systems. Recently, some smart windows have been integrated with energy storage, solar energy harvesting, self‐cleaning, and air‐purifying functions. The energy consumed by buildings and houses accounts for a considerable portion of the total energy consumed by a country as well as the world; therefore, these state‐of‐the‐art smart windows will greatly contribute to saving energy. Moreover, some multi‐functional smart windows can help in addressing environmental challenges. This mini‐review particularly focuses on discussing the recent advances made in multi‐stimuli‐responsive and multi‐functional smart windows, in addition to summarizing the researches on electrochromic, thermochromic, and other types of smart windows.

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A “Transformers”‐like nanochain for precise navigation and efficient cancer treatment

Tian,

Zeng,

et al. 2024

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Integrated multimodal imaging in theranostics nanomaterials offers extensive prospects for precise and noninvasive cancer treatment. Precisely controlling the structural evolution of plasmonic nanoparticles is crucial in the development of photothermal agents. However, previous successes have been limited to static assemblies and single‐component structures. Here, an activatable plasmonic theranostics system utilizing self‐assembled 1D silver‐coated gold nanochains (1D nanochains) is presented for precise tumor diagnosis and effective treatment. The absorbance of the adaptable core–shell chain structure can shift from visible to near‐infrared (NIR) regions due to the fusion between nearby Au@Ag nanoparticles induced by elevated H2O2 levels in the tumor microenvironment (TME), resulting in the creation of a novel 3D aggregates with strong NIR absorption. With a high photothermal conversion efficiency of 60.2% at 808 nm, nanochains utilizing the TME‐activated characteristics show remarkable qualities for photoacoustic imaging and significantly limit tumor growth in vivo. This study may pave the way for precise tumor diagnosis and treatment through customizable, optically tunable adaptive plasmonic nanostructures.

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Tailoring Broad-Band-Absorbed Thermoplasmonic 1D Nanochains for Smart Windows with Adaptive Solar Modulation

Cited by 36 publications

References 56 publications

Thermochromic Hydrogels with Dynamic Solar Modulation and Regulatable Critical Response Temperature for Energy‐Saving Smart Windows

Thermochromic Hydrogels with Dynamic Solar Modulation and Regulatable Critical Response Temperature for Energy‐Saving Smart Windows

Multi‐stimuli‐responsive and Multi‐functional Smart Windows

A “Transformers”‐like nanochain for precise navigation and efficient cancer treatment

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