Graphene-Info: the graphene experts

NanoXplore recently shared updates on its new graphene production facility in Quebec, currently housed within an existing 70,000 square foot building. The Company said that all major equipment has been delivered and secured in their physical location within the facility. Mechanical and electrical connections of the equipment are ongoing and are expected to be completed by early February.

Hydro-Québec has provided all power requirements for the commercial production of the 4,000 metric tons/year capability graphene production facility. The new graphene facility will be a fully automated production plant that will enable a connected and flexible manufacturing system. The facility will also become NanoXplore’s new Corporate Headquarters.

Graphene 3D Lab has announces that on January 23, 2020, the Company will be changing its name to G6 Materials Corp. The Company’s shares will continue to trade on the TSX Venture Exchange under the same ticker symbol (“GGG”).

The name change and updated branding reflects the Company’s evolving business strategy and greater focus on new lucrative opportunities in the field of advanced materials. The Company has already developed graphene additives for laminated carbon fiber and fiberglass composites, which are expected by the Company to significantly improve materials currently used in defense, airspace, marine, and automotive industries. The Company also established an industry partnership with a private Singaporean company, with G6 leading the development of new graphene-enhanced composite materials to be used for improved performance and durability for marine vessels and structures.

Orbex, a UK-based private, low-cost orbital launch services company, has developed what it calls an "advanced, low carbon, high performance micro-launch" rocket called "Orbex Prime" and states that it already has a customer to fly on it.

Built with 3D-printed engines and a carbon fiber-and-graphene body, Orbex Prime will utilize renewable "bio-propane" as its fuel of choice. The two-stage rocket will be designed to carry up to 150 kilograms of payload, contained within a 1.3-meter fairing, into Sun Synchronous Orbit. Orbex even says its Prime rocket will be "80% reusable", although it is rather unclear how this would be executed.

The Graphene-Info and Perovskite-Info teams are happy to announce the 2020 edition of The Perovskite Handbook. While not focused on graphene, we believe that any person interested in advanced materials and emerging technologies would find that perovskite materials are an area of focus that should not be ignored.

Perovskites are an exciting class of materials that feature a myriad of exciting properties and are considered the future of solar cells, displays, sensors, LEDs and more. The handbook is now updated to January 2020 and lists recent developments and new companies, initiatives and research activities.

Reading this book, you'll learn all about:

• Different perovskite materials, their properties and structure
• How perovskites can be made, tuned and used
• What kinds of applications perovskites may be suitable for
• What the obstacles on the way to a perovskite revolution are
• Perovskite solar cells, their merits and challenges
• The state of the perovskite market, potential and future

Directa Plus has signed an agreement with Comerio Ercole to pursue joint research and development projects using the company's G+ graphene technology.

Comerio is an Italian engineering and manufacturing company founded in 1885, that specializes in rubber and composite material processing.

Researchers from Nanjing University in China have developed a method to make large graphene films free of any wrinkles. The ultra-smooth films could enable large-scale production of electronic devices that harness the unique physical and chemical properties of graphene and other 2D materials.

Wrinkles in graphene films grown via chemical vapor deposition appear as jagged white lines at the top of this atomic force microscope image (left), but they disappear when the material is treated with a hydrogen plasma (right). Credit: Nature

Chemical vapor deposition (CVD) is the best-known method for making high-quality graphene sheets. It typically involves growing graphene by pumping methane gas onto copper substrates heated to temperatures around 1,000 °C, and then transferring the graphene to another surface such as silicon. But some of the graphene sticks to the copper surface, and as the graphene and copper expand and contract at different rates, wrinkles form in the graphene sheets. Such wrinkles often present hurdles for charge carriers and lower the film’s conductivity. Other researchers have tried to reduce wrinkles using low growth temperatures or special copper substrates, but the wrinkles have proven difficult to eliminate entirely, according to Libo Gao, a physicist at Nanjing University.

Today we published new versions of all our graphene market reports. Graphene-Info provides comprehensive niche graphene market reports, and our reports cover everything you need to know about these niche markets. The reports are now updated to January 2020.

The Graphene Batteries Market Report:

• The advantages using graphene batteries
• The different ways graphene can be used in batteries
• Various types of graphene materials
• What's on the market today
• Detailed specifications of some graphene-enhanced anode material
• Personal contact details into most graphene developers

The report package provides a good introduction to the graphene battery - present and future. It includes a list of all graphene companies involved with batteries and gives detailed specifications of some graphene-enhanced anode materials and contact details into most graphene developers. Read more here!