The global aerogel industry is experiencing unprecedented transformation as it transitions from a niche specialty materials sector into a mainstream technology platform with applications spanning electric vehicle batteries, building insulation, aerospace systems, and biomedical devices. This dynamic market evolution reflects both the unique properties of aerogels—ultralight materials with exceptional thermal insulation, high surface area, and remarkable porosity—and the growing recognition of their potential to address critical challenges in energy efficiency, thermal management, and sustainable manufacturing.

 

The aerogel landscape is undergoing rapid restructuring driven by both established players and innovative newcomers. Traditional manufacturers like Aspen Aerogels and Cabot Corporation continue advancing their core silica aerogel technologies while expanding into high-growth applications such as electric vehicle thermal barriers and advanced building insulation systems. Simultaneously, a wave of new entrants—ranging from university spin-offs to established materials companies diversifying their portfolios—are introducing novel products and competing for emerging market opportunities. This competitive environment has accelerated innovation across multiple dimensions. While silica aerogels maintain their position as the dominant commercial product category, polymer and biopolymer aerogels are gaining significant traction. Companies are developing specialized formulations targeting specific applications: carbon aerogels for energy storage electrodes, polymer aerogels for 5G telecommunications infrastructure, and bio-based aerogels for sustainable packaging and biomedical applications.

 

Manufacturing process innovation represents a critical competitive frontier. Companies are pursuing multiple strategies to reduce production costs and improve scalability, from ambient pressure drying techniques that eliminate expensive supercritical processing to continuous manufacturing systems that enhance throughput. Advanced 3D printing technologies are enabling complex aerogel geometries previously impossible to achieve, while sustainable feedstock development is addressing environmental concerns and supply chain resilience. The integration of digital technologies is significantly enhancing aerogel development and manufacturing. Computational modelling accelerates materials design, while advanced characterization techniques enable precise control over pore structure, thermal properties, and mechanical performance. These capabilities are essential for meeting increasingly stringent application requirements across diverse industries.

 

Electric vehicle applications have emerged as perhaps the most significant growth driver, with aerogels providing critical thermal management solutions for battery safety and performance. As EV adoption accelerates globally, thermal runaway protection systems incorporating aerogel barriers are becoming standard safety features, creating substantial market opportunities for specialized materials suppliers.

 

Building and construction applications continue expanding beyond traditional insulation, encompassing high-performance windows, thermal bridge solutions, and integrated building systems designed for net-zero energy performance. The aerospace and defense sectors are adopting aerogels for thermal protection systems, lightweight structural components, and advanced electronics cooling applications. Biomedical applications represent a particularly active research area, with developments in tissue engineering scaffolds, wound healing materials, and controlled drug release systems. Environmental applications, including carbon capture technologies and water purification systems, address global sustainability challenges while creating new commercial opportunities.

 

The aerogel market's trajectory reflects broader trends toward energy efficiency, sustainability, and advanced materials performance. As manufacturing costs continue declining and application knowledge expands, aerogels are positioned to become mainstream solutions across multiple industries. 

 

The Global Aerogels Market 2026-2036 provides strategic intelligence for materials manufacturers, end-users, investors, and technology developers navigating this rapidly evolving market. Analysis encompasses silica, polymer, carbon, and bio-based aerogel technologies, examining manufacturing scalability, cost structures, competitive dynamics, and emerging application opportunities through comprehensive company profiles and detailed market forecasts.

 

 Report Contents include

 

• Comprehensive analysis of aerogel properties including thermal conductivity benchmarking, density comparisons, and mechanical characteristics
• EV battery pack applications as primary growth driver with detailed thermal runaway protection analysis
• Competitive landscape assessment covering 54+ global manufacturers
• Market drivers spanning energy efficiency regulations, thermal management requirements, and sustainability mandates
• Manufacturing capacity analysis by geography with focus on China's dominance in production versus revenue
• Technology and market challenges including cost barriers, dust generation concerns, and integration complexities
• Market forecasts 2026-2036 segmented by aerogel type (silica, polymer, carbon), end-use market, and geographic region
• Technology & Materials Analysis
• Detailed aerogel classification covering inorganic, organic, and composite materials
• Manufacturing processes including supercritical drying, ambient pressure drying, and rapid extraction techniques
• Silica aerogel products: monoliths, powders, granules, blankets, boards, and renders with SWOT analyses
• Advanced composites using organic crosslinkers and fiber reinforcement
• Sustainable feedstock development from food waste, textile waste, and agricultural byproducts
• Polymer aerogels including polyimide, polyurethane, and resorcinol-formaldehyde systems
• Bio-based aerogels: cellulose nanofibers, alginate, starch, chitosan, protein, pectin, and agar materials
• Carbon aerogels, graphene aerogels, and carbon nanotube architectures
• 3D printing technologies for complex aerogel geometries
• Hybrid and composite systems including metal-organic framework aerogels
• Manufacturing & Production
• Sol-gel chemistry fundamentals and process optimization
• Supercritical CO₂ drying with closed-loop systems and autoclave technologies
• Ambient pressure drying innovations reducing production costs
• Scale-up challenges from laboratory to commercial manufacturing
• Cost analysis by aerogel type and production method
• QT-polysiloxane enabler technologies
• Applications & Markets
• EV Batteries: Thermal runaway protection, fire safety regulations (UN GTR 20, GB 38031-2020), material intensity analysis, integration strategies, and comprehensive company assessment
• Oil & Gas: Refinery insulation, cryogenic pipeline applications, LNG facilities
• Building & Construction: Sustainable insulation materials, panels, renders, plasters, window glazing systems, industrial insulation standards (EN 17956)
• Energy Storage: Silicon anodes, lithium-sulfur batteries, electrode materials, supercapacitors, hydrogen storage
• Biomedical: Drug delivery systems, tissue engineering scaffolds, wound dressings, medical implants with sterilization protocols
• Electronics & Telecommunications: EMI shielding, thermal management, 5G antenna substrates, low-loss dielectric materials
• Environmental Applications: Water treatment, heavy metal removal, oil spill remediation, CO₂ capture and direct air capture systems
• Textiles: Winter sports apparel, luxury fashion applications, protective equipment, footwear
• Aerospace & Defense: Thermal protection systems, vibration suppression, NASA applications, crash absorbers
• Additional Markets: Cold-chain packaging, cosmetics, catalysts, paints/coatings, food applications, solar energy, passive cooling
• Patent Landscape
• Analysis of 2010-2024 patent filings by technology area, assignee, and geography
• Intellectual property trends and competitive positioning
• Company Profiles Detailed profiles of 54 aerogel manufacturers including:
• Production capacity and manufacturing processes
• Product portfolios and specifications
• Target markets and applications
• Recent developments and strategic initiatives
• Companies profiled include Aerobel BV, Aerofybers Technologies, Aerogel Core Ltd., Aerogel-it, Aerogel Technologies, Aeroshield, Aspen Aerogels, Blueshift Materials, Enersens, Keey Aerogel, IBIH Advanced Materials, Krosslinker, SA-Dynamics, siloxene AG, SUMTEQ GmbH, Thermulon, Westwood Aerogel and more.....

1.1   Aerogel Properties   

1.2   Aerogel Applications

1.2.1    Application on EV Battery Packs    

1.3   Competitive Factors in the Aerogels Market   

1.4   Market Drivers and Trends    

1.5   Aerogel Manufacturer Production Capacity and Manufacturing Processes   

1.6   Market and Technology Challenges

1.7   Market Size and Forecast to 2036   

1.7.1    By Aerogel Type   

1.7.2    By End Use Market   

1.7.3    By Region   

 

 

2.1   Aerogels    

2.1.1    Origin of Aerogels   

2.1.2    Classification

2.1.3    Aerogel Forms    

2.1.4    Commercially available aerogels    

2.2   Manufacturing processes   

2.2.1    Supercritical drying process

2.2.1.1 Closed loop   

2.2.1.2 Autoclave loading    

2.2.1.3 Recent developments   

2.2.2    Ambient pressure drying process    

2.3   Silica aerogels    

2.3.1    Properties   

2.3.1.1 Thermal conductivity and density   

2.3.1.2 Mechanical    

2.3.1.3 Silica aerogel precursors   

2.3.2    Products   

2.3.2.1 Monoliths   

2.3.2.1.1    Properties   

2.3.2.1.2    Monoliths prepared under ambient pressure   

2.3.2.1.3    Scalable monolithic sheet production for windows   

2.3.2.1.4    Alternative monolithic aerogel manufacturing processes   

2.3.2.2 Powder    

2.3.2.2.1    Key characteristics   

2.3.2.2.2    Silica Aerogel powder manufacturing processes  

2.3.2.2.3    Powders and granules prepared under ambient pressure   

2.3.2.3 Granules   

2.3.2.4 Blankets    

2.3.2.5 Aerogel boards   

2.3.2.6 Aerogel renders    

2.3.2.7 Silica aerogel from sustainable feedstocks    

2.3.2.8 Silica composite aerogels    

2.3.2.8.1    Organic crosslinkers

2.3.2.8.2    Composites from powders and granules   

2.3.2.8.3    Commercial activity 

2.3.3    Cost    

2.3.4    Main Companies and Products   

2.4   Aerogel-like polymer foams

2.4.1    Properties   

2.4.2    Applications for aerogel-like polymer foams include:   

2.5   Metal oxide aerogels

2.6   Organic aerogels   

2.6.1    Polymer-based aerogels   

2.6.2    Biobased aerogels (bio-aerogels)    

2.6.2.1 Overview   

2.6.2.2 Sustainable Feedstocks   

2.6.2.2.1    Silica aerogels derived from waste sources    

2.6.2.2.1.1    Food waste  to bioaerogel conversion   

2.6.2.2.2    Commercial development   

2.6.2.2.3    Textile waste into high-value aerogel materials    

2.6.2.3 Cellulose aerogels    

2.6.2.3.1    Cellulose nanofiber (CNF) aerogels   

2.6.2.3.2    Cellulose nanocrystal aerogels   

2.6.2.3.3    Bacterial nanocellulose aerogels    

2.6.2.4 Lignin aerogels   

2.6.2.5 Alginate aerogels   

2.6.2.6 Starch aerogels    

2.6.2.7 Chitosan aerogels   

2.6.2.8 Protein aerogels   

2.6.2.8.1    Albumin aerogels   

2.6.2.8.2    Casein aerogels   

2.6.2.8.3    Gelatin aerogels   

2.6.2.8.4    Whey protein isolate aerogels    

2.6.2.9 Silk fiber    

2.6.2.10   Pectin composite aerogels for thermal superinsulation   

2.6.2.11   Agar aerogels for biomedical applications

2.6.3    Carbon aerogels    

2.6.3.1 Manufacturing and properties    

2.6.3.2 Carbon nanotube aerogels  

2.6.3.3 Graphene and graphite aerogels    

2.6.3.4 Carbon aerogel manufacturers   

2.7   3D printed aerogels  

2.7.1    3D printing processes and applications    

2.7.2    Carbon nitride    

2.7.3    Gold    

2.7.4    Cellulose    

2.7.5    Graphene oxide    

2.8   Hybrid and composite aerogels   

2.8.1    Mixed oxide aerogels

2.8.2    Metal oxide aerogel composites    

2.8.3    Carbon-based aerogel composites

2.8.4    Metal Organic Framework Aerogel Composites (MOFACs)   

 

 

3.1   Overview   

3.2   Sol-gel process   

3.3   3D printing of aerogels   

3.4   Drying methods    

3.4.1    Overview of drying methods

3.4.2    Supercritical Drying  

3.4.2.1 Closed loop   

3.4.2.2 Autoclave loading    

3.4.3    Ambient Pressure Drying    

3.4.4    Rapid Supercritical Extraction (RSCE)    

3.4.5    Advantages and disadvantages   

3.5   Costs 

3.6   Manufacturing scale-up challenges    

 

 

4.1   Competitive landscape    

4.2   EV Batteries    

4.2.1    Overview   

4.2.2    EV batteries    

4.2.2.1 Fire protection    

4.2.2.2 Thermal barriers    

4.2.2.3 Regulations    

4.2.2.4 Challenges   

4.2.2.5 Integration of aerogels with specialized foam materials  

4.2.2.6 Companies    

4.3   Oil and Gas    

4.3.1    Overview   

4.3.2    Applications  

4.3.2.1 Refineries   

4.3.2.2 Pipelines   

4.4   Building and Construction   

4.4.1    Overview   

4.4.2    Types of sustainable insulation materials  

4.4.3    Applications  

4.4.3.1 Panels and blankets 

4.4.3.2 Plaster, concrete and bricks

4.4.3.3 Coatings and paints 

4.4.3.4 Windows/Daylighting    

4.4.3.5 Industrial insulation 

4.5   Energy Storage   

4.5.1    Overview   

4.5.2    Applications  

4.5.2.1 Silicon anodes   

4.5.2.2 Li-S batteries 

4.5.2.3 Electrodes   

4.5.2.4 Thermal insulation    

4.5.2.5 Supercapacitors    

4.6   Biomedical   

4.6.1    Overview   

4.6.2    Applications  

4.6.2.1 Drug delivery 

4.6.2.2 Tissue engineering   

4.6.2.3 Medical implants   

4.6.2.4 Wound care   

4.7   Cold-Chain Packaging    

4.7.1    Overview   

4.8   Electronics and Telecommunications   

4.8.1    Overview   

4.8.2    Applications  

4.8.2.1 EMI Shielding

4.8.2.2 Thermal insulation    

4.8.2.3 5G   

4.8.2.3.1    Antenna modules    

4.8.2.3.2    High-performance antenna substrates   

4.8.2.3.3    Advanced low-loss materials   

4.9   Filtration, Separation, and Sorption   

4.9.1    Overview   

4.9.2    Applications  

4.9.2.1 Sorbents for liquids, hazardous ions (heavy metal ions) (e.g., water treatment)    

4.9.2.2 Sorbent for oil spills 

4.9.2.3 Sorbents for gases (CO2, hazardous gases, VOC)

4.10   Textiles    

4.10.1 Overview   

4.10.2 Applications  

4.10.2.1   Winter sports apparel   

4.10.2.2   Consumer apparel    

4.10.2.3   Protective equipment    

4.10.2.4   Footwear applications   

4.11   Food   

4.11.1 Overview   

4.12   Catalysts    

4.13   Paint and Coatings    

4.14   Aerospace and Defence   

4.14.1 Overview   

4.14.2 Applications  

4.14.2.1   Thermal protection systems

4.14.2.2   Crash absorbers    

4.14.2.3   Defense applications    

4.15   Cosmetics    

4.15.1 Overview   

4.16   Other markets and applications    

4.16.1 Sports equipment    

4.16.2 Fire retardant applications  

4.16.3 Solar energy collection    

4.16.4 Knudsen pumps    

4.16.5 Passive Cooling   

 

 

5.1   Patent applications  

 

 

7.1   Report scope

7.2   Research methodology   

 

 

 

 

 

Table1 General properties and value of aerogels

Table2 Aerogel Thermal Conductivity and Density Benchmarking

Table3 Growing EV Market

Table4 Market drivers for aerogels

Table5  Aerogel Manufacturer Production Capacity and Manufacturing Processes

Table6 Planned aerogel production expansions

Table7 Market and technology challenges in aerogels

Table8 Aerogel Forecast 2021-2036 (Million USD), by aerogel type

Table9 Aerogel Forecast 2021-2036 by Markets (Million USD)

Table10 Aerogel Manufacturers in China

Table11 Aerogel Forecast 2021-2036 by Region (Million USD)

Table12 Aerogel Form Factors

Table13 Commercially Available Aerogel Products

Table14 Silica aerogel properties 

Table15 Chemical precursors used to synthesize silica aerogels

Table16 Commercially available aerogel-enhanced blankets

Table17 Commercial Silica Composite Aerogels

Table18 Main manufacturers of silica aerogels and product offerings

Table19 Typical structural properties of metal oxide aerogels

Table20 Polymer aerogels companies

Table21 Types of biobased aerogels

Table22 Carbon aerogel companies

Table23 Carbon aerogel manufacturers

Table24  3D printing processes and applications

Table25 Synthesis methods-Aerogels synthesised, advantages and disadvantages

Table26 Silica Aerogel Powder Manufacturing Processes Using Ambient Drying

Table27 Drying methods for aerogel production

Table28 Advantages and disadvantages of drying methods

Table29 Silica Composite Aerogels - Cost Analysis

Table30 Cost Analysis by Aerogel Type

Table31 Market overview of aerogels in automotive-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL

Table32 Properties of Aerogels and Other Fire Protection Materials

Table33 Types of Fire Protection Materials

Table34 Thermally Insulating Fire Protection Products for EVs

Table35 Comparison of Aerogels vs Other Fire Protection Materials

Table36 Comparison of Aerogel Fire Protection Materials for EV Batteries

Table37 Companies producing  Aerogels for EV Batteries

Table38 Market overview of aerogels in oil and gas-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL

Table39 Aerogel Products for Cryogenic Insulation

Table40 Market overview of aerogels in building and construction-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL

Table41 Aerogel Materials for Building & Construction Applications

Table42 Aerogel Products for Windows/Daylighting

Table43 Market overview of aerogels in energy conversion and storage-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL

Table44 Market overview of aerogels in drug delivery-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL

Table45 Market overview of aerogels in tissue engineering-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL

Table46 Market overview of aerogels in medical implants-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL

Table47 Market overview of aerogels in wound care-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL

Table48 Market overview of aerogels in cold-chain packaging-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL

Table49 Market overview of aerogels in electronics and Telecommunications-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL

Table50 Aerogel Products for Electronic Appliances

Table51 Market overview of aerogels in filtration, separation, and sorption-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL

Table52 Market overview of aerogels in textiles- market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL

Table53 Market overview of aerogels in food- market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL

Table54 Market overview of aerogels in catalysts-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL

Table55 Market overview of aerogels in paints and coatings-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL

Table56 Market overview of aerogels in aerospace-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL

Table57 Market overview of aerogels in cosmetics-market drivers, types of aerogels utilized, motivation for use of aerogels, applications, TRL

Table58 Other markets and applications for aerogels

Table59 Aerogel patents 2010-2024

 

 

Figure1 Classification of aerogels

Figure2 SLENTEX® thermal insulation

Figure3 Aerogel Forecast 2021-2036 (Million USD), by aerogel type

Figure4 Aerogel Forecast 2021-2036 by Markets (Million USD)

Figure5 Aerogel Forecast 2021-2036 by Region (Million USD)

Figure6 Main characteristics of aerogel type materials

Figure7 Classification of aerogels

Figure8 Canada Goose luxury footwear

Figure9 Flower resting on a piece of silica aerogel suspended in mid air by the flame of a bunsen burner

Figure10 Monolithic aerogel

Figure11 Aerogel granules

Figure12 Internal aerogel granule applications

Figure13 Slentite

Figure14 Methods for producing bio-based aerogels

Figure15 Types of cellulose aerogel

Figure16 Lignin-based aerogels

Figure17 Fabrication routes for starch-based aerogels

Figure18 Schematic of silk fiber aerogel synthesis

Figure19 Graphene aerogel

Figure20 Commonly employed printing technologies for aerogels

Figure21 Schematic for direct ink writing of silica aerogels

Figure22 3D printed aerogel

Figure23 Schematic of silica aerogels synthesis

Figure24 Formation of aerogels, cryogels and xerogels

Figure25 Aerogel engineering strategies

Figure26 3D printed aerogels

Figure27 SEM images of the microstructures of (a) alginate and (b) pectin aerogels obtained by supercritical drying, (c) cellulose aerogels by freeze-drying, and (d) silica-cellulose composite aerogels by ambient drying

Figure28 Methods of gel drying

Figure29 Pyrogel insulation on a heat-exchange vessel in a petrochemical plant

Figure30 Aerogel construction applications

Figure31 Incorporation of aerogels into textiles

Figure32 Aerogel dust collector

Figure33 Thermal Conductivity Performance of ArmaGel HT

Figure34 A pencil resting on a PyroThin thermal barrier to show its comparative thickness

Figure35 SLENTEX® roll (piece)

Figure36 CNF gel

Figure37 Block nanocellulose material

Figure38 Keey Aerogel

Figure39 Fire-resistance in Keey Aerogel

Figure40 Melodea CNC suspension

Figure41 HIP AERO paint

Figure42 Insulation of various aerogel fibres illustrated using the example of a cushion,       

Figure43 Sunthru Aerogel pane

Figure44 Quartzene®