Infrared Regulating Smart Window Based on Organic Materials

Khandelwal, Hitesh; Schenning, Aphj Albert; Debije, MG Michael

doi:10.1002/aenm.201602209

Cited by 308 publications

(221 citation statements)

References 152 publications

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“…[1][2][3][4][5] They are recognized as a suitable "green" nanotechnology, because do not impede visibility as other conventional blinding systems, providing, at the same time, glare control, thermal, and visual comfort management. Electrochromic (EC) smart windows, or dynamic tintable glazings, belong to the promising category of products changing their light transmittance in response to external stimuli, like electric field or sunlight irradiance.…”

Section: Introductionmentioning

confidence: 99%

Simplified All‐Solid‐State WO₃ Based Electrochromic Devices on Single Substrate: Toward Large Area, Low Voltage, High Contrast, and Fast Switching Dynamics

Cossari

Pugliese

Simari

et al. 2020

Adv Materials Inter

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Electrochromic devices (ECDs) represent one of the most promising energy saving and solar control technology for the market of energy‐efficient building and optoelectronic devices. A continuous and intense effort is currently devoted to the development of effective solid‐state ECDs and their integration in multifunctional systems, such as photoelectrochromics. Here, the fabrication of simplified all‐solid‐state WO3 based ECDs on single‐substrate is reported, demonstrating how the rational design of highly interconnected WO3 columnar nanostructures with Nafion polymer matrix remarkably decreases the charge transport barrier at the hybrid electrolyte/electrochromic interface (EEI), thus determining an impressive improvement of overall device performances. The soft polymer substrate of the electrolyte plays a key role on the formation of WO3 pillar‐like structures and on the increase of interfacial contact area by affecting the vacuum‐deposition WO3 growth. Apart from providing higher transmittance in bleached state, the resulting device, entirely manufactured at room temperature by bottom‐up process, exhibits lower activation voltages (0.5–3 V) and faster switching kinetics (5–10 s) compared with monolithic ECDs based on both bulk and mesoporous WO3 films. Furthermore, the enhanced EEI enables the scale‐up on large area and flexible substrate ensuring simultaneously a wide optical contrast (ΔT = 70%), and high coloration efficiency.

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Section: Introductionmentioning

confidence: 99%

Simplified All‐Solid‐State WO₃ Based Electrochromic Devices on Single Substrate: Toward Large Area, Low Voltage, High Contrast, and Fast Switching Dynamics

Cossari

Pugliese

Simari

et al. 2020

Adv Materials Inter

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“…To save the energy NIR shielding materials can be used as coatings in buildings and cars to reduce the heat transmission through their outer surfaces. These coatings can be divided into inorganic materials (such as heat-reflective glasses) [1,3,6,7] and polymer composites with inorganic fillers (such as indium tin oxide-ITO, antimony tin oxide-ATO, lanthanum hexaboride-LaB 6 , tungsten oxide-WO 3 nanoparticles) [4,[8][9][10][11]. The fillers should possess high absorption or high reflectance of infrared radiation.…”

Section: Introductionmentioning

confidence: 99%

Graphene Oxide with Controlled Content of Oxygen Groups as a Filler for Polymer Composites Used for Infrared Radiation Shielding

Mazurkiewicz-Pawlicka

Nowak

Małolepszy

et al. 2019

Nanomaterials

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Infrared (IR) shielding materials are commonly used for different applications, such as smart windows or optical filters. Infrared radiation is responsible for about 50% of the energy coming from the sun. During a hot summer or cold winter a lot of energy is needed to keep the optimal temperature inside buildings and means of transport. To reduce the heat transmission and save energy IR shielding materials can be used as coatings made of polymer composites. Graphene oxide (GO) and its reduced forms have interesting IR absorption properties and might be used as a filler in a polymer matrix for IR shielding applications. Graphene oxide can be reduced by different methods. Depending on the reduction method reduced graphene oxide (rGO) with a different content of oxygen can be obtained exhibiting different properties. In this work we propose new polymer nanocomposites with poly(vinyl alcohol) as the matrix and 0.1 wt.% addition of graphene materials with different oxygen content to be used for IR shielding applications. The results show that the properties of the graphene filler strongly influence the infrared shielding properties of the obtained nanocomposites. The best IR shielding properties were obtained for the composites where rGO with the lowest oxygen content was used.

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“…LCs have been extensively applied in flat panel LC displays (LCDs) as the active switching components. Recently, their potential in numerous beyond display applications have been demonstrated and intense research and development activities in this direction is actively pursued to capitalize on the unique attributes of LC materials . Apart from technological applications, LCs provide greater and deeper insight into the fundamental understanding of self‐assembly and self‐organization of matter at different hierarchical levels .…”

Section: Introductionmentioning

confidence: 99%

“…Recently,t heir potentiali nn umerous beyond display applica-tions have been demonstrated and intense research and development activities in this direction is actively pursued to capitalize on the unique attributes of LC materials. [8][9][10][11][12][13][14][15][16][17] Apart from technological applications, LCs provideg reater and deeper insight into the fundamental understanding of self-assembly and self-organization of matter at different hierarchical levels. [18][19][20][21][22][23][24][25][26][27][28] Extreme sensitivity of LCs to different external stimuli of small magnitude qualifies them as functionals timuli-responsive soft materials.…”

Section: Introductionmentioning

confidence: 99%

The Halogen Bond: An Emerging Supramolecular Tool in the Design of Functional Mesomorphic Materials

Wang

Bisoyi

Urbas

et al. 2018

Chemistry A European J

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Owing to their dynamic attributes, non-covalent supramolecular interactions have enabled a new paradigm in the design and fabrication of multifunctional material systems with programmable properties, performances, and reconfigurable traits. Recently, the "halogen bond" has become an enticing supramolecular synthetic tool that displays a plethora of promising and advantageous characteristics. Consequently, this versatile and dynamic non-covalent interaction has been extensively harnessed in various fields such as crystal engineering, self-assembly, materials science, polymer chemistry, biochemistry, medicinal chemistry and nanotechnology. In recent years, halogen bonding has emerged as a tunable supramolecular synthetic tool in the design of functional liquid-crystalline materials with adjustable phases and properties. In this Concept article, the use of halogen bond in the field of stimuli-responsive smart soft materials, that is, liquid crystals is discussed. The design, synthesis and characterization of molecular and macromolecular liquid crystalline materials are described and the modulation of their properties has been emphasized. The power of halogen bonding in offering a large variety of functional liquid crystalline materials from readily accessible mesomorphic and non-mesomorphic complementary building blocks is highlighted. The article concludes with a perspective on the challenges and opportunities in this emerging endeavor towards the realization of enabling and elegant dynamic functional materials.

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Infrared Regulating Smart Window Based on Organic Materials

Cited by 308 publications

References 152 publications

Simplified All‐Solid‐State WO₃ Based Electrochromic Devices on Single Substrate: Toward Large Area, Low Voltage, High Contrast, and Fast Switching Dynamics

Simplified All‐Solid‐State WO₃ Based Electrochromic Devices on Single Substrate: Toward Large Area, Low Voltage, High Contrast, and Fast Switching Dynamics

Graphene Oxide with Controlled Content of Oxygen Groups as a Filler for Polymer Composites Used for Infrared Radiation Shielding

The Halogen Bond: An Emerging Supramolecular Tool in the Design of Functional Mesomorphic Materials

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Infrared Regulating Smart Window Based on Organic Materials

Cited by 308 publications

References 152 publications

Simplified All‐Solid‐State WO3 Based Electrochromic Devices on Single Substrate: Toward Large Area, Low Voltage, High Contrast, and Fast Switching Dynamics

Simplified All‐Solid‐State WO3 Based Electrochromic Devices on Single Substrate: Toward Large Area, Low Voltage, High Contrast, and Fast Switching Dynamics

Graphene Oxide with Controlled Content of Oxygen Groups as a Filler for Polymer Composites Used for Infrared Radiation Shielding

The Halogen Bond: An Emerging Supramolecular Tool in the Design of Functional Mesomorphic Materials

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Simplified All‐Solid‐State WO₃ Based Electrochromic Devices on Single Substrate: Toward Large Area, Low Voltage, High Contrast, and Fast Switching Dynamics

Simplified All‐Solid‐State WO₃ Based Electrochromic Devices on Single Substrate: Toward Large Area, Low Voltage, High Contrast, and Fast Switching Dynamics