By submitting this form, you are agreeing to the Terms of Use and Privacy Policy.
3D Through the use of chemical vapor deposition (CVD) processes, graphene foam is created, which is a porous, highly-surface-area form of the material. The features of a metallic foam are combined with the special mechanical and electrical capabilities of two-dimensional graphene to create graphene foam, a very light, highly conductive material with exceptional strength and flexibility.
Applications for this cutting-edge material are still being researched. Chemical sensors made of graphene foam have been proven to be nearly 10 times more effective than sensors now available on the market. Most volumes of American Elements 3D graphene foam are typically accessible.
A graphene foam is robust, conductive, and suitable for a variety of applications, including materials for sensors and purification/absorption. Graphene aerogels, in which the liquid portion of the gel is replaced by a gas, and graphene foams share some similarities (usually air).
The Global 3D Graphene foam market accounted for $XX Billion in 2023 and is anticipated to reach $XX Billion by 2030, registering a CAGR of XX% from 2024 to 2030.
A new commercial product called Graphene Flex Foam has been unveiled by Graphene 3D Lab and will be sold on Graphene Supermarket, the online store operated by Graphene Laboratories.
A conductive elastomer composite and an ultra-lightweight graphene foam are combined to create the new product, which is referred to as a Multilayer Freestanding Flexible Graphene Foam.
Together, the composite and foam, a highly conductive 3D chemical vapor deposition, combine the best aspects of many graphene applications.
The material’s porous nature and flexibility as a flexible foam make it easy to use and handle. It is also lightweight and changeable.
The Graphene Flex Foam might be used with other graphene-related materials, like the filament options from Graphene 3D Lab, to create electronics and other conductive goods.
According to G3L, the novel product is a great substrate choice for making lithium-ion battery electrodes. Since wearable materials will require flexible electronics, sensors, and conductive qualities, wearable electronics is a natural application.
The business also thinks that this ground-breaking invention will pave the way for the development of flexible batteries and supercapacitors in the foreseeable future.
Any company interested in a freestanding, stable, ultralight, highly conductive material that can stretch with their product and fit into any area may be interested in this discovery. The Graphene Flex Foam may be produced in any shape or size.
The brand change also serves as a benchmark for the change from an R&D firm to an Advanced Materials Manufacturer.
The hyper-sensitive 3D graphene foam Gii-Sens electrodes from Integrated Graphene (formerly RD Graphene), which enables biosensors with the capability to bring laboratory tests to the point of need and enable quick testing, are being introduced to the Human Diagnostics market.
They are able to draw on their experience working with diagnostics manufacturers by offering a broad range of assay and device development services as a spin-off from their R&D roots.
The possibilities are unlimited because Integrated Graphene is perfectly situated to deliver on the graphene promise across markets with a solution that is at last prepared to satisfy market demands.
This company’s flagship graphene product, which they are launching under their new Integrated Graphene brand, will be the first step in an ambitious commercial path that will see them become the top manufacturer of pure 3D Graphene Foam in the world.
Graphene foam aids in converting mechanical energy into electrical energy. Researchers were able to convert “wasted” energy from human movement into electricity with the use of a graphene foam substance.
A team from the Institute of Thin Films, Sensors and Imaging (ITFSI) at the University of the West of Scotland (UWS) created a new triboelectric nanogenerator (TENG) with the goal of powering small electrical devices and Internet of Things (IoT) sensors.
As an active layer in the novel generator, the team used 3D graphene foam material Gii from Stirling firm Integrated Graphene. The study demonstrated that a human footprint may generate enough energy on a pressure-sensitive mat fitted with Gii-TENG sensors to secretly monitor who enters and leaves a space.
Through our work with Integrated Graphene, we have demonstrated the viability of using Gii-material, a sophisticated form of three-dimensional graphene (3DG) foam, as an active layer in triboelectric nanogenerators to generate energy for autonomous sensors and electronics.
The mats might monitor building occupancy, manage room temperature as people enter and exit, and provide information for carbon dioxide monitoring in addition to tracking energy usage.
Other possibilities might include self-powered wearable biosensors for diabetes, gout, and cardiovascular disease early detection, as well as machinery that harnesses mechanical energy from vehicles and pedestrians.
