Graphene production research, scalable manufacturing methods, reactor design, carbon conversion, and industrial process development.
Researchers have utilized a single-spin quantum sensor to directly image magnetotransport at graphene-metal interfaces, revealing how Lorentz deflection and contact resistance shape current flow.
A proposed contactless growth architecture utilizes argon pressure cushions and graphene nanoparticles to eliminate the wasteful slicing process in semiconductor manufacturing, potentially reducing silicon waste by up to 70 percent.
Explore a proposed shift from traditional Czochralski ingot growth to a contactless, graphene-seeded method that could reduce silicon waste by up to 70 percent.
Researchers have developed a high-performance supercapacitor electrode by fusing liquid gallium and indium with reduced graphene oxide into a lightweight aerogel, combining fast charging with high energy density.
This technical exploration examines how varying the length of chitosan chains on graphene sheets affects the loading and stability of the anticonvulsant Primidone, identifying a dimer configuration as the optimal carrier for improved bioavailability.
Scientists have demonstrated that adding graphene to indium-cadmium sulfide photocatalysts more than triples hydrogen production from water splitting, achieving rates of 4.97 μmolh−1cm−2 through enhanced charge transport and interfacial activity.
New research demonstrates that graphene buffer layers dramatically improve the ordering of iron phthalocyanine molecules on nickel substrates, opening pathways for more efficient molecular spintronic devices by reducing unwanted substrate interactions while preserving electronic properties.
New research reveals how adding graphene to dental plastics dramatically reduces coffee staining and color changes caused by saliva pH shifts, offering a pathway to longer-lasting, better-looking temporary dental restorations.
Explore how researcher Francesca Grilli utilized graphene oxide nanocarriers and complex 3D tumor models to develop a more effective, cancer-specific gene therapy strategy for lung cancer.
Explore how graphene’s unique electrical properties and massive surface area are revolutionizing environmental sensors, enabling the detection of pollutants and gases at the parts-per-billion level with unprecedented sensitivity.
Explore how the unique electrical and mechanical properties of graphene are transforming soft robotics by creating flexible, highly sensitive electronic skins capable of detecting pressure and vibration.
Discover how researchers are using graphene-based nanocomposites to create lightweight radiation shielding that could revolutionize space travel and avionics by reducing dependence on heavy lead.
An in depth technical exploration into the use of graphenated-polyaniline nanocomposite sensors for the precise electro-oxidation and determination of anthracene.
A breakthrough in breast cancer diagnostics utilizes a novel sandwich-type electrochemical immunosensor. By combining gold nanoparticle-decorated ZIF-8 and nitrogen-doped graphene quantum dots, researchers have achieved unprecedented sensitivity in detecting the BRCA1 biomarker.
A groundbreaking study reveals the direct observation of electric polarization switching via domain wall sliding in tetralayer graphene, opening new frontiers for 2D nanoelectronics and optical readouts.
An in-depth analysis of hydrogen binding energies and density-of-states distributions in large-area graphene, exploring how isotopic tagging and oxide layer thickness reveal the precise mechanics of carbon-hydrogen bond dissociation.
A deep dive into groundbreaking molecular dynamics research revealing how graphene coatings on alumina surfaces manipulate the tangential momentum accommodation coefficient to dramatically reduce aerodynamic drag in rarefied atmospheric environments.
A deep dive into groundbreaking research on how the angular alignment between encapsulating boron nitride layers dictates anomalous gating and hysteresis in bilayer graphene systems.
An in-depth exploration of how wedge disclinations and magnetic flux manipulate the Dirac states and information-theoretic properties of graphene quantum rings.
An in-depth analysis of a novel manufacturing framework designed to continuously fabricate boron and graphene-derived conductive nanothreads within strictly controlled inert environments.
An in-depth exploration of a novel manufacturing framework designed to synthesize and continuously extract boron-derived conductive graphene nanothreads in a highly controlled, inert environment, paving the way for next-generation semiconductor materials.
New research reveals how asynchronous mass inversion driven by trigonal warping and displacement fields generates unexpected quantum anomalous Hall states in multilayer graphene.
A breakthrough in van der Waals heterostructure fabrication demonstrates that polyvinyl alcohol-assisted exfoliation combined with elevated-temperature lamination yields graphene devices capable of exhibiting the Hofstadter butterfly spectrum, challenging the long-held assumption that polymer exposure degrades quantum transport.
A detailed technical analysis of how researchers are transforming cotton textile waste into highly efficient reduced graphene oxide nanostructures to remove the antibiotic Rifampicin from wastewater streams.