Graphene Supercapacitors: Introduction and News

Skeleton Technologies has announced the first close of a larger funding round at €33 million. This brings its total venture capital funding to €392 million in preparation for its planned initial public offering (IPO) in the United States in 2027.

The new round expands Skeleton’s investor base with the addition of Axon Partners Group, SmartCap, and Taiwania Capital. More investors will be announced as part of a larger round ahead of the IPO.

Researchers from the University of California, Lawrence Livermore National Laboratory and Lawrence Berkeley National Laboratory recently developed a graphene-enabled 3D printing platform that addresses a fundamental limitation in electrochemical energy storage: the tradeoff between electrode thickness and transport efficiency.

While thicker electrodes increase energy density by incorporating more active material, they typically suffer from poor ion transport and high resistance. To overcome this, the team designed interpenetrating 3D electrode architectures using an acrylate-based resin infused with graphene oxide (GO). The inclusion of GO enables the fabrication of highly porous, conductive structures that support both efficient ion diffusion and electron transport throughout ultra-thick electrodes.

Researchers from the Shanghai Institute of Technology, Naval University of Engineering and Liaoshen Industries Group have developed a highly porous NiCo₂V₂O₈@GO hollow sphere electrode material that could improve supercapacitor performance. This innovation tackles the persistent challenge of low energy density in supercapacitors, which excel in power delivery and cycle life but lag behind batteries in stored energy.

The team first explored a series of ternary metal vanadates - NiₓCo₃₋ₓV₂O₈, NiₓMn₃₋ₓV₂O₈, and NiₓCu₃₋ₓV₂O₈ (x = 1, 1.5, 2) - to pinpoint optimal metal combinations for electrochemical activity. They then refined NiCo₂V₂O₈@GO via anion exchange on metal glycerolate precursors, followed by annealing to form yolk-double-shell hollow nanospheres coated with graphene oxide (GO). This core-shell design leverages GO's 2D scaffold to prevent nanoparticle aggregation, boost electrical conductivity, and expand the electrochemically accessible surface area.

Carbon-Ion Energy has announced that it is re-examining the integration of graphene into its supercapacitors in collaboration with graphene producers Levidian and HydroGraph, which supply ultra-pure graphene (99.9% and 99.8% purity). Both companies use advanced combustion-based methods that produce highly consistent graphene.

The company has experience with graphene since the mid-2010s, having previously collaborated with other graphene suppliers. Carbon-Ion believes newer graphene structures may enhance ion transport and energy storage efficiency in their supercapacitors by optimizing inter-layer spacing and morphology.

Researchers from China's Dalian Jiaotong University and South China Academy of Advanced Optoelectronics have developed a graphene-based electrode for supercapacitors using a novel slit evaporation self-assembly process. The resulting freestanding sulfuric acid-treated reduced graphene oxide/commercial graphene (S-ATrGO/CG) films demonstrate excellent energy storage capabilities and durability, potentially benefitting graphene-enhanced supercapacitors.

The team introduced a capillary slit-assisted self-assembly method that leverages narrow glass slits to guide the controlled stacking of graphene flakes during solvent evaporation. This process promotes highly ordered, laminated structures, reducing the common issue of flake restacking that limits ion transport in conventional graphene films. Capillary forces, combined with π–π interactions and electrostatic attraction, ensure that sulfuric acid-treated graphene oxide (ATGO) and commercial graphene (CG) align into continuous, freestanding films with high structural integrity.

Researchers from Sungkyunkwan University and Hubei University of Technology have reported a scalable and cost-effective process to produce an all-solid-state asymmetric micro-supercapacitor based on nanostructured flower-like MoS₂/graphene cathode and activated carbon anode. The MoS₂/graphene nanocomposites were synthesized via a hydrothermal method, leveraging the synergistic effect of pseudocapacitive MoS₂ and highly conductive graphene to enhance electrode capacitance and cycling stability. 

Facile bar-coating and laser cutting techniques were used to fabricate the asymmetric micro-supercapacitor. The device has a stable operating voltage of 1.6 V, and achieves an impressive area capacitance of 183.7 mF cm⁻², and a maximum area energy density of 65.3 mWh cm⁻², which the team says is the highest areal energy density among MoS₂-based micro-supercapacitors.

Skeleton Technologies is accelerating its expansion in the United States as demand for AI infrastructure strains power grids nationwide. As part of this expansion, the company recently announced the opening of a new engineering facility in Houston, Texas.

Data center power consumption in the U.S. is projected to more than double by the end of the decade. AI data centers are not only energy-intensive but also have highly variable power profiles, creating sharp demand spikes that grid infrastructure is not designed to handle. This strain increases the risk of outages and forces utilities to build more power plants and upgrade equipment, which can drive higher electricity prices. Skeleton’s solutions enable AI data centers to smooth out their power demand profiles and reduce energy consumption by up to 45 percent. As a result, Skeleton significantly reduces the burden that AI data centers place on the electric grid and enables data center operators to extract more computing power with a lower energy footprint.

Today we published a new edition of our Graphene Supercapacitors Market Report, with all the latest information. The supercapacitor market and industry is facing high demand and graphene is a pivotal material for this application. The report is now updated to February 2026, with all the latest projects, news and research results.

Reading this report, you'll learn all about:

• The advantages of using graphene in supercapacitors
• Various types of graphene materials
• Market insights and forecasts
• What's on the market today

The report package also provides:

• A list of all graphene companies involved with supercapacitors
• Prominent research activity in this field
• Free updates for a year

This Graphene Supercapacitors market report provides a great introduction to graphene materials used in the supercapacitor market, and covers everything you need to know about graphene in this niche. This is a great guide for anyone involved with the supercapacitor market, nanomaterials, electric vehicles and mobile devices.

Researchers at the International Advanced Research Centre for Powder Metallurgy and New Materials (ARCI) in India have reported high-voltage supercapacitors based on a dual-functional porous graphene carbon nanocomposite (PGCN) electrode, which could be beneficial for applications like solar panels and also provide electric vehicles with increased range and faster acceleration.

Conventional electrolytes used in commercial supercapacitors can operate between 2.5–3.0 V and begin to decompose or face safety issues (such as flammability) at higher voltages. The team's new design was able to reach 3.4 V, which the scientists defined as 'unprecedented', overcoming the 3.0 V limitation of conventional supercapacitors along with significantly improved energy storage. This work addresses electrolyte instability, doubling energy density to provide electric vehicles with increased range and faster acceleration while simplifying module design through reduced cell stacking.

Skeleton Technologies is reported to have officially opened its €220 million SuperFactory in Markranstädt, near Leipzig, which is already delivering graphene-based supercapacitors to Siemens, General Electric and Hitachi Energy for European electrical grids, as well as to major US hyperscalers for AI infrastructure. The Leipzig plant is framed as a key hub in a fully European value chain, supplying high‑power, fast‑charging energy storage for AI data centers and grid‑stability projects as part of a broader energy‑transition and AI‑infrastructure strategy.

Notably, the road to full production has not been smooth. The factory had originally been planned to start production and ramp up in 2024, but equipment and supplier issues pushed completion of the final lines and full ramp‑up into 2025, prompting some public talk of Skeleton “failing to launch the plant in time,” even though the project itself was not cancelled. During this period Skeleton shut its older Dresden site and laid off staff in Estonia, which added to the perception problems, but the company now presents the Leipzig SuperFactory as opened, producing and delivering at scale