Silica–Resorcinol–Melamine–Formaldehyde Composite Aerogels as High-Performance Thermal Insulators

Civioc, Romain; Malfait, Wim J.; Lattuada, Marco; Koebel, Matthias M.; Galmarini, Sandra

doi:10.1021/acsomega.1c04462

Cited by 6 publications

(5 citation statements)

References 60 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The experiment was carried out in 2 partslaser light ray projection on the screen without aerogel and ray projection filling Aerogel LUMIRA® LA 1000 CABOT (Civioc et al 2022) (translucent and hydrophobic aerogel granules ranging in size from 70 μm to 4 mm, thermal conductivity 18 mW/(mK)) in Fresnel lens construction with 7 cm aerogel layer between Fresnel lens and focus point. What mechanical exposure can be on aerogel?…”

Section: Methodology and Laboratory Testmentioning

confidence: 99%

“…Experimental setup. 25 ml of Aerogel LUMIRA® LA 1000 CABOT (Civioc et al 2022) (translucent and hydrophobic aerogel granules ranging in size from 70 μm to 4 mm, thermal conductivity 18 mW/(mK)) was measured and placed in a glass jar. An example of aerogel was taken for testing under the microscope with 40 x zoom to take pictures of aerogel before mechanical exposure (Guo et al 9021).…”

Section: Entrepreneurship and Sustainability Issuesmentioning

confidence: 99%

“…Many adaptive materials are mimicked from nature, for instance, conifer cones that have repetitive opening-closing cycles and structural properties to respond to humidity. Civioc et al(Civioc et al 2022) classified the materials into four areas: temperature-reactive materials, light-reactive materials, humidity-reactive materials, and carbon dioxide-reactive materials. The author classifies 13 smart materials, and 13 adaptive materials and lists their stimulus.…”

mentioning

confidence: 99%

See 2 more Smart Citations

Low energy buildings: multifunctional strategies and solutions

Gargasas,

Bazienė,

Dzienis

2023

JESI

View full text Add to dashboard Cite

EU directive on the Energy Performance of Buildings states that by 2020 new construction buildings must be Nearly Zero Energy Buildings (NZEB). These are common goals for the EU, however, it creates a challenge for northern countries where climate requests higher energy efficiency materials and respectively the costs. NZEB achieves low energy consumption, solar gains, and reduces heat losses, therefore, has very high energy performance. Passive solar heat gains and its utilization is widely used to reduce energy consumption, especially, through windows in the South façade. Research and experiments of solar simulation models deliver results that allow evaluating potential gains from solar thermal façade systems; in addition, it reduces heat losses for buildings to reach the requirements of NZEB. The goal of the research is to assess latent and sensible energy storage in building envelopes using phase change material (PCM) as a heat accumulator and Fresnel lens as a solar concentrator. A new passive solar thermal façade system model is designed that consists of a Fresnel lens as solar concentrator, PCM as heat accumulator, and copper as heat transfer enhancer to accumulate thermal energy received from the Sun or solar simulator. This research is an example that biology can be integrated with architecture via biomimicry principles and nature has countless multi-functional, complex, and highly responsive mechanisms, strategies, and solutions. Biomimicry in architecture remedies existing errors of efficient system design and products, by taking into the fact that outer shells in nature face the same weather conditions and have the same functions and tasks as reducing heat loss via thermal envelope (insulation, metabolism, hibernation), storing and generating energy, avoiding indoor from overheating.

show abstract

Section: Methodology and Laboratory Testmentioning

confidence: 99%

Section: Entrepreneurship and Sustainability Issuesmentioning

confidence: 99%

mentioning

confidence: 99%

See 1 more Smart Citation

Low energy buildings: multifunctional strategies and solutions

Gargasas,

Bazienė,

Dzienis

2023

JESI

View full text Add to dashboard Cite

show abstract

“…[ 212 ] Consequently, numerous polymer‐based aerogels have been reported, and can be synthesized by varying the phenolic resin chemistry (phenol‐furfural (PF), [ 34 ] cresol‐formaldehyde, [ 32 ] melamine‐formaldehyde, [ 31 ] ) based on the polymer type, such as polyurethane (PU), [ 35 ] polyurea, [ 91 ] polybenzoxazine, [ 35 ] poly(vinyl alcohol), [ 213 ] and PI's, [ 16 ] and based on soluble polymers (polystyrene (PS), [ 214 ] polyacrylonitrile, [ 215 ] and PEDOT:PSS). Most of the polymeric aerogels contain polymer chains cross‐linked by covalent bonds, such as RF, [ 216 ] PF, [ 33 ] and PI aerogels. [ 217 ] RF aerogels are synthesized by addition–polycondensation, which can be performed under acidic and basic pH conditions.…”

Section: Development Of Mechanically Strengthened Aerogels: Tradition...mentioning

confidence: 99%

Mechanically Strengthened Aerogels through Multiscale, Multicompositional, and Multidimensional Approaches: A Review

Parale,

Kim,

Choi

et al. 2024

Advanced Materials

View full text Add to dashboard Cite

In recent decades, aerogels have attracted tremendous attention in academia and industries as a lightweight and porous multifunctional nanomaterial. Despite their wide application range, their limited mechanical durability hinders their processing and operation, particularly in application requiring complex physical structures. “Mechanically strengthened aerogels” have emerged as the potential solution to address this drawback. Since the first report on aerogels in 1931, various modified synthesis processes have been introduced to enhance the mechanical strength of aerogels in the last decade, further advancing their multifunctional scope. This review summarizes the state‐of‐the‐art developments of mechanically strengthened aerogels through multicompositional and multidimensional approaches in the past 10 years. Additionally, new trends and future technologies for the commercialization of aerogels as much as plastic is discussed in the final section.This article is protected by copyright. All rights reserved

show abstract

“…XG is a porous, architectured material emanating from varying drying strategies of wet gels . Thus, the enchanting and peculiar attributes of these porous materials are garnered from the peculiar exibility as well as resilience of the sol-gel fabrication procedure, garnered in synergy with either ambient drying (X-G) or supercritically a liated drying (A-G) [81][82][83][84][85][86][87][88][89][90][91][92][93][94][95][96][97][98][99][100]. As already elucidated, these substrates have been fabricated from varying precursors, like carbon, silica, and biopolymeric entities and possessing differing biological, physical, chemical, and mechanical, attributes, relative to varying parameters, including precursoral substrates, solvent medium, as well as drying parameters [101][102][103][104][105][106][107][108][109][110][111][112][113][114][115][116][117][118][119][120].…”

Section: Challenges and Future Perspectivesmentioning

confidence: 99%

Characterization and Fabrication of Xerogel Polymeric Nanocomposites and Multifunctional Applications

Idumah

2022

Preprint

View full text Add to dashboard Cite

Xerogel (X-G)@polymeric nanocomposites are hybrid nanomaterials constituted of xerogels (X-Gs) synergized with polymeric materials with enclosed nanoparticulates in either physical or covalently inclined cross-linking with one another and/or with the nano-substrates. X-G@biopolymeric bionanocomposites are hybrid bionanomaterials constructed by synergizing biopolymeric matrices with dispersed organic or inorganic nanoparticulates with improved properties for multifunctional applications. Hence, this paper elucidates novel trends in synthesis, construction, characterizations, properties and multifunctional applications of X-G@polymeric nanocomposites.

show abstract

Silica–Resorcinol–Melamine–Formaldehyde Composite Aerogels as High-Performance Thermal Insulators

Cited by 6 publications

References 60 publications

Low energy buildings: multifunctional strategies and solutions

Low energy buildings: multifunctional strategies and solutions

Mechanically Strengthened Aerogels through Multiscale, Multicompositional, and Multidimensional Approaches: A Review

Characterization and Fabrication of Xerogel Polymeric Nanocomposites and Multifunctional Applications

Contact Info

Product

Resources

About