Graphene composites: introduction and market status

Premier Graphene has announced that its Mexican affiliate, HGI Industrial Technologies S.A.P.I., has secured two new contracts to supply the Mexican military. The agreements cover the provision of military tactical belts and nylon-cotton ripstop fabric, both considered mission-critical materials within active defense supply programs. HGI and Premier have already initiated coordination with suppliers, manufacturers, and logistics partners to support timely execution of the contracts.

The company indicated that these awards reflect growing institutional confidence in HGI’s capabilities, following prior defense-related supply engagements. The contracts are expected to contribute to recurring revenue streams and demonstrate the company’s ability to operate across multiple supply categories within the defense sector.

Researchers from IMDEA Materials Institute, Polytechnic University of Madrid, University Rey Juan Carlos, Universidad Politécnica de Madrid (UPM), National Institute for Aerospace Technology (INTA) and Universidad Francisco de Vitoria have developed a multifunctional fiber-reinforced polymer composite that integrates strain sensing, electromagnetic shielding and thermal management within a structural laminate.

The team fabricated laser-induced graphene (LIG) directly on Kevlar fabric via laser photothermal conversion, then incorporated this LIG@Kevlar layer into basalt fiber/biobased epoxy laminates using vacuum infusion, a process compatible with industrial-scale manufacturing. This in-situ conversion strategy avoids separate LIG films or transfer steps, helping to maintain interlaminar integrity and eliminating foreign interfaces that could otherwise weaken the composite.

Plaid Technologies has announced significant progress in the development of its graphene-infused concrete composite (Plaid-GCC) technology, demonstrating performance improvements in laboratory testing.

"We're witnessing a perfect storm in the construction materials market," said Guy Bourgeois, Chief Executive Officer of Plaid Technologies. "Infrastructure spending is at historic highs, labor shortages are driving time-to-completion pressures, and increasingly stringent building requirements coupled with new carbon regulations are making traditional cement increasingly expensive. Our laboratory results indicate that graphene-enhanced concrete will be transformational - potentially essential for contractors who need to build faster, cleaner, stronger."

Volt Carbon Technologies has provided an update on its operations, highlighting ongoing commercialization efforts and expanded activities in graphene-related materials.

Over the past three years, Volt has generated modest revenues through mineral processing services and advanced materials development programs, as reported in its Management’s Discussion and Analysis filings. While these revenues have not been material, they have helped offset a portion of operating costs as the company continues to prioritize process development and commercial readiness.

Premier Graphene, a developer of advanced graphene-based defense and protective-wear fortification technologies, along with its Mexican affiliate, HGI, recently secured their first contract with the Dirección General de Fábrica de Vestuario y Equipo (FAVE), a division of Mexico’s Secretaría de la Defensa Nacional (DEFENSA). This achievement marks a strategic entry into Mexico’s defense manufacturing ecosystem and establishes both companies as emerging participants within its procurement framework. This also opens the door to working with other Latin American Countries. 

As a Mexican company, HGI facilitated this contract with its established network within Mexico’s manufacturing infrastructure, combined with the coordination and support of Lic. Emmanuel Hernández Rico. The award follows governmental agency’s direct request for proposal prompted by our uniquely fabricated, specialized belt assemblies with integrated magazine (ammunition) carriers, designed to meet demanding operational requirements, including protecting military personnel.

Adisyn has announced that 2D Generation's  subsidiary, 2D Radar Absorbers, has entered into a binding License and Research Agreement with Ramot, the technology transfer company of Tel Aviv University (“TAU”). The agreement grants Adisyn exclusive, worldwide rights to commercialize graphene-based radar signature reduction technology, marking a transition from research to a structured commercial development phase. 

This agreement comes at a time of increasing global focus on radar signature management, driven by the rapid expansion of UAV deployment, Loitering Munitions, and the growing sophistication of detection systems across defence and aerospace sectors. 

Adisyn recently completed an initial proof-of-concept program demonstrating that graphene-enhanced composite materials can reduce radar reflection characteristics, with laboratory testing confirming up to 20dB reduction in radar reflection.

The program was conducted in collaboration with Ramot, the technology transfer company of Tel Aviv University. Composite samples were tested under controlled laboratory conditions and demonstrated up to 20dB reduction in radar reflection coefficient relative to baseline materials. The research team is now working on further optimization, targeting up to a 30dB reduction. According to Adisyn, a reduction of that magnitude would shrink the actual physical radar cross-section – the size of a target as detected by radar – by a factor of 1,000.

A University of Cambridge research team has developed a triaxial force microsensor array using graphene-liquid metal composites, enabling robots to sense force magnitude, direction, slip, and surface roughness at scales rivaling human fingertips. This achievement addresses key limitations in tactile sensing for neuroprosthetics, human-machine interfaces, and dexterous robotics by decoupling normal and tangential forces through multiscale pyramid microstructures.

The device employs anisotropic porous conductive elastomers (APEs) with a hybrid filler of spiky nickel particles, few-layer graphene nanosheets, and eutectic gallium-indium (EGaIn) liquid metal microdroplets. These form a solid-liquid conductive network where LM droplets act as deformable hubs bridged by graphene sheets, cured under magnetic fields to align fillers directionally within an interconnected microporous structure. Pyramid-shaped units, as small as 200 μm across, mimic human epidermal microstructures to concentrate stress at tips, boosting sensitivity while spanning wide force ranges.

Researchers from China's Northeastern University, Shenyang Jusheng New Material Technology, Key Laboratory of Medical Image Computing, Shenyang Aerospace University and Australia's University of New South Wales have developed a polyurea-based nanocomposite spray sensing coating reinforced with covalently functionalized graphene nanoplatelets, offering a scalable solution for structural health monitoring in demanding environments.

Preparation and Main Properties of Graphene NanoPlatelet-functionalized Polyurea Coatings.

Structural health monitoring (SHM) in harsh and complex conditions remains challenging, as conventional sensors often lack conformability, mechanical durability, and long-term stability. In their recent study, the team outlines a new approach - a spray-applied polyurea nanocomposite sensing coating that integrates functionalized graphene nanoplatelets to combine robust mechanical performance with reliable, real-time damage and strain monitoring for infrastructure and automotive structures.

Graphene Composites USA (GC USA) has announced that its ultralight GC Patrol Shield® has become "the first and only rifle-rated ballistic shield to pass and receive third-party verification for rifle and shotgun rounds under the ASTM E3347-25 standard (Standard Specification for Ballistic-Resistant Shields Used by Law Enforcement Officers)".

Third-Party verified edge-shot protection and real-world durability at half the weight of conventional shields could have great potential for Law Enforcement safety.