Regulatory mechanism of highly transparent, low-thermal-conductivity aerogel film for energy-efficient windows

Nyachieo Kennedy Momanyi , Peng Zhao , Xingyu Liu , Ningfei Sun , Tonghua Hu , Jianyu Sun , Yong Xie , Limin Liu

Soft Science ›› 2025, Vol. 5 ›› Issue (3) : 27

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Soft Science ›› 2025, Vol. 5 ›› Issue (3) :27 DOI: 10.20517/ss.2025.10
Research Article

Regulatory mechanism of highly transparent, low-thermal-conductivity aerogel film for energy-efficient windows

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Abstract

Aerogels are a focus of research in energy-saving materials due to their unique nanoporous structure. However, achieving aerogels with simultaneously high transparency, low thermal conductivity, and remarkable mechanical robustness remains a challenge. Herein, a highly transparent, low thermal conductivity, and mechanically robust silica aerogel is fabricated through sol-gel process combined with supercritical drying. By systematically optimizing the concentrations of methyltrimethoxysilane, cetyltrimethylammonium bromide, urea, and acetic acid in solution, we obtained an aerogel film with transparency of 97.83 % in the visible spectrum, thermal conductivity of 0.0149 W·m-1·K-1, and maximum compressive strain of 27%. When applied as a sandwich material between double glass, it demonstrates significantly enhanced thermal insulation performance while maintaining transparency comparable to that of conventional glass. Furthermore, the silica aerogel film exhibits exceptional hydrophobicity due to the presence of methyl groups, which enhances its structural stability. Consequently, this high-performance silica aerogel film demonstrates strong potential for energy-saving windows, making it an ideal candidate for retrofitting existing buildings and integrating into emerging architectural glazing systems.

Keywords

Silica aerogel film / high transparency / low thermal conductivity / mechanical robustness / energy-saving window

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Nyachieo Kennedy Momanyi, Peng Zhao, Xingyu Liu, Ningfei Sun, Tonghua Hu, Jianyu Sun, Yong Xie, Limin Liu. Regulatory mechanism of highly transparent, low-thermal-conductivity aerogel film for energy-efficient windows. Soft Science, 2025, 5(3): 27 DOI:10.20517/ss.2025.10

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Pérez-lombard L,Pout C.A review on buildings energy consumption information.Energy Build2008;40:394-8

[2]

Zhao P,Hu S.Flexible and transparent bagasse aerogels for thermal regulation glazing.ACS Sustainable Chem Eng2023;11:9711-20

[3]

Smalyukh II.Thermal management by engineering the alignment of nanocellulose.Adv Mater2021;33:e2001228

[4]

Abraham E,Senyuk B.Highly transparent silanized cellulose aerogels for boosting energy efficiency of glazing in buildings.Nat Energy2023;8:381-96

[5]

Aguilar-Santana JL,Velasco-Carrasco M.Review on window-glazing technologies and future prospects.Int J Low Carbon Technol2020;15:112-20

[6]

Yan M,Cheng X.“Robust-soft” anisotropic nanofibrillated cellulose aerogels with superior mechanical, flame-retardant, and thermal insulating properties.ACS Appl Mater Interfaces2021;13:27458-70

[7]

Sun X,Wo Z,Zhang X.A dual-crosslinked macroporous aerogel with enhanced mechanical durability for efficient solar-driven desalination of seawater and wastewater.J Mater Chem A2024;12:29538-49

[8]

Wang C,Xu H,Li Y.A review of high-temperature aerogels: composition, mechanisms, and properties.Gels2024;10:286 PMCID:PMC11121034
[9]

Zhao S,Drdova S.Additive manufacturing of silica aerogels.Nature2020;584:387-92

[10]

Cotana F,Moretti E.Multipurpose characterization of glazing systems with silica aerogel: in-field experimental analysis of thermal-energy, lighting and acoustic performance.Build Environ2014;81:92-102

[11]

Lian M,Liu S.Highly porous yet transparent mechanically flexible aerogels realizing solar-thermal regulatory cooling.Nanomicro Lett2024;16:131 PMCID:PMC10897091
[12]

Illera D,Gomez H.Cellulose aerogels for thermal insulation in buildings: trends and challenges.Coatings2018;8:345

[13]

Long LY,Wang YZ.Cellulose aerogels: synthesis, applications, and prospects.Polymers2018;10:623 PMCID:PMC6403747
[14]

Wang X,Wu Z.Enhanced mechanical stability and hydrophobicity of cellulose aerogels via quantitative doping of nano-lignin.Polymers2023;15:1316 PMCID:PMC10007250
[15]

Liu J,Shi F.A facile pore size controlling strategy to construct rigid/flexible silica aerogels for super heat insulation and VOCs adsorption.Chem Eng J2022;450:138196

[16]

Hayase G,Nakanishi K.Structure and properties of polymethylsilsesquioxane aerogels synthesized with surfactant n-hexadecyltrimethylammonium chloride.Micropor Mesopor Mat2012;158:247-52

[17]

Gupta P,Chhajed M.Surfactant assisted in situ synthesis of nanofibrillated cellulose/polymethylsilsesquioxane aerogel for tuning its thermal performance.Macromol Rapid Commun2023;44:2200628

[18]

Payanda Konuk O,Yousefzadeh H.The effect of synthesis conditions and process parameters on aerogel properties.Front Chem2023;11:1294520 PMCID:PMC10627014
[19]

Smith DS,Bourret J.Thermal conductivity of porous materials.J Mater Res2013;28:2260-72

[20]

Harvey A,Boland JB.Non-resonant light scattering in dispersions of 2D nanosheets.Nat Commun2018;9:4553 PMCID:PMC6212482
[21]

Wang J,Ren S.Transparent thermal insulation silica aerogels.Nanoscale Adv2020;2:5504-15 PMCID:PMC9417477
[22]

Li C,Dong W.A review of silicon-based aerogel thermal insulation materials: performance optimization through composition and microstructure.J Non Cryst Solids2021;553:120517

[23]

Fu Z,Papathanasiou T.Critical review on the thermal conductivity modelling of silica aerogel composites.J Build Eng2022;57:104814

[24]

Michael M,Jin Q,Overend M.A systematic review and classification of glazing technologies for building façades.Energies2023;16:5357

[25]

Lee O,Jin Yim T,Yoo K.Determination of mesopore size of aerogels from thermal conductivity measurements.J Non Cryst Solids2002;298:287-92

[26]

Roiban L,Rong Q.Advanced three dimensional characterization of silica-based ultraporous materials.RSC Adv2016;6:10625-32

[27]

Zhan W,Kong Q.The synthesis and polymer-reinforced mechanical properties of SiO2 aerogels: a review.Molecules2023;28:5534 PMCID:PMC10384082
[28]

Zhao P,Momanyi NK.Black aerogel based on short-time high-flux He ion implantation.Adv Funct Mater2025;35:2408995

[29]

Hunt AJ.Light scattering for aerogel characterization.J Non Cryst Solids1998;225:303-6

[30]

Zhao L,Bhatia B,Wang EN.Modeling silica aerogel optical performance by determining its radiative properties.AIP Adv2016;6:025123

[31]

Likins-White M,Zhai Z.Degradation of insulating glass units: thermal performance, measurements and energy impacts.Buildings2023;13:551

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