Graphene applications: what is graphene used for?

NanoGraf, an advanced battery material company, announced earlier this month the successful completion of the first large volume production run of its M38 18650 cell for the U.S. military.

Nanograf, formerly called SiNode Systems, pursues advances in Lithium-ion battery anodes for a wide range of industries from consumer electronics to electric vehicles. NanoGraf explaines that it uses a proprietary silicon alloy-graphene material architecture to overcome the silicon anode technical hurdles. The combination of silicon-based alloys and a flexible 3D graphene network helps stabilize the active material during charge and discharge. The company’s manufacturing process is different from others that rely on expensive and complex vapor deposition-based systems. Instead, a wet chemistry process has been developed that is highly scalable and already proven in a multi-ton-scale pilot manufacturing line in Japan. The anode material drops into existing electrode mixing and coating equipment and has been validated in large-scale battery manufacturing facilities.

NTT Corporation, along with The University of Tokyo and National Institute for Materials Science (NIMS), showed that graphene plasmon wave packets can be generated, manipulated and read out on-chip using terahertz electronics.  

The team managed to electrically generate and control graphene plasmon wave packets with a pulse width of 1.2 picoseconds. This result shows that the phase and amplitude of a terahertz signal can be controlled electrically by using graphene plasmons. It enables terahertz signal processing, a method different from conventional electrical circuit technology using transistors and is expected to contribute to realizing ultrahigh-speed signal processing in the future.

Black Swan Graphene has announced a commercial agreement with Broadway Colours, a UK-based manufacturer of color and additive masterbatches, plastic compounds and rotational molding powders. The Company said the partnership aims to leverage Broadway’s technical expertise, manufacturing capabilities, distribution, and market reach to fast-track the commercialization of Black Swan’s graphene products.

Broadway will use Black Swan’s graphene nanoplatelets to manufacture their Graphene Enhanced Masterbatches (GEMs) targeting a variety of sectors including consumer goods, packaging, automotive, construction, defense, marine and logistics. Its new product range will also feature a bio-based polymer GEM, which Black Swan highlighted offers an eco-friendly alternative to the existing products.  

The Abu Dhabi Department of Economic Development (ADDED) has signed a Memorandum of Understanding (MOU) with Inovartic Investment, a technology innovation company, to establish a facility in Abu Dhabi that will produce graphene and graphene-enhanced products.

The strategic collaboration marks a step towards enhancing advanced material manufacturing in the region and beyond and is aligned with Abu Dhabi’s vision to become a global hub for cutting-edge industries and technological innovation.

Inbrain Neuroelectronics has designed a brain implant that can both read signals and stimulate brain impulses. Its brain-computer interface (BCI) uses graphene to create a high-resolution interface with the brain. Now, the Company has announced it is gearing up for its first-in-human testing, planed for this summer.

The technology is a type of brain-computer interface (BCI), which have been used for medical diagnostics, as communication devices for people who can’t speak, and to control external equipment, including robotic limbs. However, Inbrain intends to transform its BCI technology into a therapeutic tool for patients with neurological issues such as Parkinson’s disease. 

Researchers from the University of Manchester, University of Cambridge, Khalifa University and Universidade Federal do Ceará have developed a new device using graphene to transform next-generation technologies in hydrogen fuel cells, computing, and catalysis.

Image credit: Khalifa University 

The team's research shows that the properties of a graphene sheet can be fine-tuned with the help of electric fields to independently host proton and electron currents, thus setting the stage for a device that serves both computer memory and logic functions.

Researchers from the University of North Carolina at Chapel Hill, Carnegie Mellon University, North Carolina State University and Yale University have developed a novel method to enhance the efficiency and stability of solar-driven, carbon-dioxide reduction.

Image credit: Applied Materials and Interfaces

This new technique involves the use of “fuzzy” graphene to improve the performance of semiconductor-based photoelectrodes, which initialize electrochemical transformations following the absorption of light. The term fuzzy refers to a form of graphene that has a rough or irregular surface with a porous and three-dimensional (3D) structure, as opposed to smooth or flat layers, with enhanced properties like surface area, reactivity or adhesion to a silicon molecule, or substrate.

Specialist structural flooring manufacturers Staircraft have been testing the use of Haydale's graphene-based functional ink for application on their innovative chipboard flooring system. Significant investment has reportedly been made to get the new flooring system to adopt a heating solution that is cost effective and easy to install.

In a recent trial, Staircraft has reported very encouraging results and is now focused on continuing to collect definitive data before introducing the concept to their customer base. 

As part of an effort to promote self-reliance, the Indian government's Defense Research and Development Organization (DRDO) has granted seven new projects to private MSMEs and start-ups in the defense industry, under the Technology Development Fund scheme. 

One of these projects aims to develop graphene-Based smart & e-textiles for multifunctional wearable applications. Alohatech has been granted funding for this project, which will focus on developing conductive yarn and fabric-making processes using graphene nanomaterials and conductive inks. 

Limb neuroprostheses aim to restore motor and sensory functions in amputated or severely nerve-injured patients. These devices use neural interfaces to record and stimulate nerve action potentials, creating a bidirectional connection with the nervous system. Most neural interfaces are based on standard metal microelectrodes. 

Left: a histological section of the nerve implanted with an electrode longitudinally. Right, an image of the sciatic nerve with an EGNITE electrode implanted transversely to allow stimulation and recording of nerve impulses. Image credit: UAB

Researchers at the Autonomous University of Barcelona (UAB) and ICN2 have demonstrated in animal models how Engineered Graphene for Neural Interface (EGNITE), a derivative of graphene, allows the creation of smaller electrodes, which can interact more selectively with the nerves they stimulate, thus improving the efficacy of the prostheses. The study also demonstrated that EGNITE is biocompatible, showing that its implantation is safe.