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Graphene is the world's strongest, thinnest and most conductive material, made from carbon. Graphene's remarkable properties enable exciting new applications in electronics, solar panels, batteries, medicine, aerospace, 3D printing and more!

Recent graphene News

Researchers from India use graphene oxide to design a novel anti-cancer system

Jun 25, 2017

Researchers at the Indian Institute of Science Education and Research (IISER) Pune have used graphene oxide to develop a novel cancer drug delivery system. The researchers' achievement relies on a rather surprising revelation - they found that when a FDA-approved anticancer drug cisplatin was added, the graphene oxide sheets self-assembled into spherical nanoparticles enclosing the drug within.

Lab tests showed that the nanoparticles (of 90-120 nanometre in size) containing cisplatin and either of two other anticancer drugs ( proflavine and doxorubicin) were taken up by cervical cancer cells leading to programmed cell death.

Chinese team created graphene aerogels inspired by plant structure

Jun 22, 2017

Researchers at Zhejiang University in China have designed a graphene-based aerogel mimicking the structure of the "powdery alligator-flag" plant that could have potential for use in applications like flexible electronics.

Graphene aerogel based on plant structure image

The team drew inspiration from the stem structure of the powdery alligator-flag plant (Thalia dealbata), a strong, lean plant capable of withstanding harsh winds. The researchers used a bidirectional freezing technique that they previously developed to assemble a new type of biomimetic graphene aerogel that had an architecture like that of the plant's stem. When tested, the material supported 6,000 times its own weight and maintained its strength after intensive compression trials and was resilient. They also put the aerogel in a circuit with a LED and found it could potentially work as a component of a flexible device.

Graphene nanocapsules improve Li-S battery electrodes

Jun 22, 2017

Researchers at the Argonne National Laboratory and Oregon State University in the U.S have designed a novel cathode architecture for lithium-sulphide batteries that consists of crystalline di-lithium sulphide nanoparticles encapsulated in few-layer graphene. The design is said to allow the maximum amount of active sulphur species to be incorporated into the electrode and so greatly improves its electrical conductivity. It also overcomes many of the major challenges associated with existing sulphur electrodes and di-lithium composites.

The Li2S-graphene nanocapsules architecture can boast superior electrochemical properties. The electrodes have a high reversible capacity of 1160 mAh/g and area capacity of 8.1 mAh/cm2. The team synthesized the Li2S@graphene nanocomposites in a one-step reaction in which they reacted lithium metal foils with CS2 vapour carried by argon gas at 650°C. Li2S nanocrystals and the tight wrapper of few-layer graphene are spontaneously generated, thus forming the nanocapsules. The Li2 nanoparticles are between 50 and 80 nm in size and are uniformly and seamlessly encapsulated in about 10–20 graphene layers. This significantly reduces the charge-transfer resistance between the two materials and greatly improves the electric conductivity of Li2.

Scientists use lasers to 3d print graphene foams

Jun 22, 2017

Researchers at Rice University and China's Tianjin University have used 3D laser printing to fabricate centimeter-sized graphene objects. The team has demonstrated the making of graphene foams from non-graphene starting materials, in a method that could reportedly be scaled for additive manufacturing applications with pore-size control. The process is conducted at room temperature, without the need for molds. The rather unusual starting materials are powdered sugar and nickel powder.

Rice U team 3D prints graphene using lasers image

3D laser printers work differently than the more familiar extrusion-based 3D printers, which create objects by squeezing melted plastic through a needle as they trace out two-dimensional patterns. In 3D laser sintering, a laser shines down onto a flat bed of powder. Wherever the laser touches powder, it melts or sinters the powder into a solid form. The laser is rastered, or moved back and forth, line by line to create a single two-dimensional slice of a larger object. Then a new layer of powder is laid over the top of that layer and the process is repeated to build up three-dimensional objects from successive two-dimensional layers.

Directa Plus joins Alfredo Grassi in a project to develop graphene-enhanced clothing

Jun 22, 2017

Directa Plus logoDirecta Plus, a producer and supplier of graphene-based products, has teamed up with clothing manufacturer Alfredo Grassi to develop graphene-enhanced clothing, workwear, uniforms and more. This joint development agreement follows a trial of Directa’s graphene by Alfredo to assess the potential benefits of incorporating graphene into their products.

The initial focus under the deal will be on garments with linings printed with Graphene Plus combined with waterproof, breathable textiles. The presence of G+ graphene, which has reportedly been independently certified as non-toxic and non-cytotoxic, produces a technically advanced fabric with unique properties, the company claims.

Researchers from India extract graphene from flowers

Jun 20, 2017

A team of scientists from the Center for Materials for Electronics Technology (C-MET) and Savitribai Phule Pune University (SPPU) in India has reportedly managed to extract graphene from wild flowers (bougainvillea vines).

According to the scientists at C-MET and SPPU, these flowers, when dried and chemically treated, can be used to extract graphene. The team has fabricated supercapacitors using the produced graphene, and is now undertaking final trials of their performance. The experiment involved programmed heating of the dried petals, at temperatures ranging from 250 degrees Celsius to 1,000 degrees Celcius.

Exeter team develops technique for improved graphene-based sensors

Jun 20, 2017

Exeter researchers have recently reported a new method to use graphene to produce photodetectors, which they feel could revolutionize the manufacturing of vital safety equipment, such as radiation and smoke detection units.

Exeter team's improved sensors image

The Exeter team has created a new type of photodector that is said to be able to sense light around 4500 times better than traditional graphene sensors. This could possibly be implemented to create sensoring and imaging equipment that is more stable in harsh conditions, as well as been smaller and most cost-effective. The team stated that “In this work we demonstrate that dressing the structure of graphene with molecules can transform the optical and electrical response of this wonder material and enable unprecedented applications”.

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