Articles tagged with Graphene
Pratyanik Sau, a senior at the University of Texas at Arlington, won an Outstanding Undergraduate Student Oral Presentation Award for his research on graphene using positrons. The study has implications for designing particle accelerators and fusion reactors.
A new technique for detecting long wave infrared photons of different wavelengths has been developed by UCF researchers. This method, based on a nanopatterned graphene, offers dynamic spectral tunability and ultrafast response times, surpassing existing cooled and uncooled detectors.
Researchers at NYU Tandon School of Engineering have discovered new growth-directed graphene stacking domains that can be self-assembled without manual twisting or alignment. These domains are well-suited for enabling unconventional quantum Hall effects, superconductivity, and charge density waves.
Researchers create high-quality hexagonal boron nitride (hBN) films just one atom thick using a new growth method. The films exhibit excellent insulating properties and are suitable for high-performance electronic devices.
Researchers at the University of Jena have developed a method to functionalise graphene without interference, allowing for ultrasensitive detection of biomarkers. This breakthrough enables rapid, cost-effective diagnostics using graphene-based field-effect transistors.
Physicists at MIT have made a breakthrough discovery that sheds light on the conditions that lead to exotic electronic states in graphene and other two-dimensional systems. Through calculations, they show that pentalayer graphene can exhibit fractional charge without a magnetic field.
Researchers from FSU and National High Magnetic Field Laboratory found that twisted bilayer graphene's conductivity depends on minute geometry structure changes upon interlayer twisting. The study reveals the potential of multilayer moiré systems in constructing materials with on-demand optical properties.
The new biosensor detects symmetric dimethylarginine in urine, providing a more accurate indicator of kidney health than creatinine. It can identify mild kidney impairment and offers a reliable alternative to blood tests, enabling timely interventions and potential long-term outcomes.
Researchers at Empa's nanotech@surfaces laboratory have developed a method to link many spins in a controlled manner, enabling precise measurement of their interactions. This achievement brings theoretical models of quantum physics one step closer to reality.
Researchers at Northwestern University have developed a new surface that prevents 100% of frost formation on flat areas for up to 160 hours. The hybrid surface combines a textured macrotexture with a thin layer of graphene oxide, offering a promising solution for various applications.
Researchers developed a more sustainable 3D-printed concrete material combining graphene with limestone and calcined clay cement. The new material offers enhanced strength and durability while significantly reducing carbon emissions, making it a powerful solution for addressing environmental challenges in 3D printed construction.
Researchers merged science and art to create a new kind of ceramic with enhanced strength and heat resistance. The team's innovative technique uses graphene oxide and ultrasound to produce delicate and intricate structures previously unattainable in traditional ceramics.
Researchers from KAIST have developed a new hydrogen production system that overcomes current limitations of green hydrogen production. The system uses a water-splitting process with an aqueous electrolyte, achieving high energy density and long-term stability.
A new technological design increases graphene production while maintaining quality, utilizing a Faraday cage to optimize energy and reduce waste. The study shows significant improvement in efficiency, producing 5.2 milligrams of graphene per minute and watt compared to the original 4.3 milligrams.
Researchers at Chalmers University of Technology have developed a graphene-based, ultra-thin antibacterial material that can kill 99.9% of bacteria on surfaces, including medical devices and implants. The new technology uses fridge magnet technology to control the orientation of graphene flakes, making it possible for practical applica...
A Spanish-German team has shown that the ferromagnetic element cobalt significantly enhances spin textures in graphene-iridium hybrids. The samples were grown on insulating substrates, which is a necessary prerequisite for multifunctional spintronic devices exploiting these effects.
Researchers at PNNL create a uniform two-dimensional layer of silk protein fragments on graphene, enabling the design and fabrication of silk-based electronics. This biocompatible system has potential applications in wearable and implantable health sensors, as well as computing neural networks.
Researchers at Harvard University have developed a new device that can easily twist and study 2D materials, opening up new possibilities for discovering new phases of matter. This innovation uses micro-electromechanical systems to control the twist angle, making it easier to produce unique samples and study their properties.
Researchers at Kumamoto University have created a new form of graphene oxide without internal pores, significantly improving hydrogen ion barrier properties. The non-porous film exhibits up to 100,000 times better performance than conventional films, with potential applications in protective coatings and rust prevention.
Researchers create silver nanoparticles infused with azithromycin that effectively break down biofilms and unveil a new sensing method to assess antimicrobial activity. The novel approach offers a promising solution against antibiotic-resistant bacteria, with potential applications in coating medical devices.
A pioneering technique for producing large-scale graphene current collectors has been developed to significantly enhance the safety and performance of lithium-ion batteries. The new process allows for the production of graphene foils with customizable thicknesses, which could lead to even more efficient and safer batteries.
Scientists create sheets of transition metal chalcogenide 'cubes' connected by chlorine atoms, exhibiting high catalytic efficiency for hydrogen generation. The discovery opens up a new route to assembling nanosheets with unique electronic and physical properties.
Scientists at National University of Singapore have created electron-hole crystals in an exotic quantum material, paving the way for advancements in computing technologies. The breakthrough was achieved using scanning tunneling microscopy and reveals two distinct ordered patterns at different energy levels.
A new graphene-based material, EGNITE, enhances the performance of neuroprostheses by improving electrode size and selectivity. In animal models, EGNITE showed improved muscle activation and biocompatibility, paving the way for potential clinical translation.
Researchers successfully controlled Andreev bound states in bilayer graphene-based Josephson junctions using gate voltage, observing changes in real-time and confirming theoretical predictions. The discovery enables adjustment of energy levels, opening potential for diverse applications.
A research team has developed a method to strengthen graphene nanolayers by cross-linking them with rotaxanes, improving the material's stretchability and toughness. The new films show increased tensile strength, elasticity, and toughness, making them suitable for flexible electronics and composite materials.
Researchers at Columbia University and colleagues have developed a new method to synthesize large-area graphene without oxygen, leading to reproducible and high-quality samples. The technique eliminates trace oxygen, which has previously affected the growth rate and quality of graphene.
The researchers created a chemosensor that detects lactic acid levels in saliva without the need for an electrical power source, opening up possibilities for easy use in remote locations. The sensor uses graphene foam technology to measure changes in quantum capacitance when lactate binds, allowing for lower-cost and more reliable trac...
Researchers at Tel Aviv University developed a method to grow ultra-long and narrow graphene nanoribbons with semiconducting properties, opening doors for technological applications in advanced switching devices and spintronic systems. The study's success demonstrates a breakthrough in carbon-based nanomaterials.
Researchers from Tokyo Institute of Technology experimentally revealed that high-density Ca introduction enhances superconductivity in graphene-calcium compounds through confinement epitaxy, leading to increased critical temperatures. This breakthrough could enable the development of C6CaC6 superconductors with wide applicability in qu...
Researchers at the University of Illinois and the University of Duisburg-Essen have developed a new method to probe the electronic properties of 2D materials using ion irradiation. The technique, which uses ions instead of laser light, enables highly localized and short-time excitations in the material, allowing for high-precision stud...
Researchers at ETH Zurich directly detected electron vortices in graphene using a high-resolution magnetic field sensor. The vortices formed in small circular disks with different diameters and were observed to reverse the flow direction.
Researchers at The University of Manchester have successfully achieved robust superconductivity in high magnetic fields using a newly created one-dimensional system. This breakthrough holds profound potential for advancements in quantum technologies, particularly in the quantum Hall regime.
Scientists at POSTECH create conducting polymers with exceptional electrical conductivity, rivaling graphene's performance. The breakthrough achieves ultrafast electron mobility and long phase coherence length, overcoming a major challenge in organic semiconductors.
The researchers used an optomechanical methodology to extract the thermal expansion coefficient, specific heat, and thermal conductivity of five different materials, including graphene and ultra-thin silicon membrane. This method provides a route toward improving our understanding of heat transport in the 2D limit.
Scientists develop method to image thermally-induced rearrangement of 2D materials at the atomic scale, observing a new grain-seeding mechanism and aligned domain growth. This discovery enables control over macroscopic twist between layers, affecting material properties.
An international research team has demonstrated that electrons in naturally occurring double-layer graphene move like particles without any mass, similar to light. This discovery has the potential to develop tiny, energy-efficient transistors at a nanoscale.
Researchers from Lehigh University have developed a material that promises over 190% quantum efficiency in solar cells, exceeding the theoretical limit for silicon-based materials. The material's 'intermediate band states' enable efficient absorption of sunlight and production of charge carriers.
Physicists at Princeton University have successfully visualized the Wigner crystal, a quantum phase of matter composed of electron crystals. The team used a scanning tunneling microscope to directly image the crystal, confirming its properties and enabling further study.
Researchers visualize chiral interface state at atomic scale for the first time, allowing on-demand creation of conducting channels. The technique has promise for building tunable networks of electron channels and advancing quantum computing.
Scientists developed crack-free nanocellular graphene through liquid metal dealloying, exhibiting high tensile strength and conductivity. The material showed excellent performance in a sodium-ion battery, including high rate capabilities, long life, and deformation resistance.
A team of UMass Amherst engineers has developed a tissue-like bioelectronic mesh system that can simultaneously measure the electrical signal and physical movement of cells in lab-grown human cardiac tissue. This breakthrough device allows researchers to observe how the heart's mechanical and electrical functions change during developm...
Researchers at University of Würzburg successfully crafted a functional protective layer for indenene, a two-dimensional quantum semiconductor material. The graphene-based coating protects the material from oxidation and corrosion, enabling its use in air or chemical environments.
A comprehensive review of graphene and related materials' health and ecological risks has been published, with no serious acute cell-damaging effects observed. The study investigated various applications and life cycles of graphene-containing materials, finding that stress reactions can occur in lung cells but recover quickly.
Researchers at MIT have observed a rare electronic state in which electrons become fractions of their total charge without the need for external magnetic fields. This effect, known as the fractional quantum anomalous Hall effect, has significant implications for the development of topological quantum computing.
Researchers at Umea University have developed a new, non-toxic method to produce high-quality graphene oxide with significantly fewer defects. This breakthrough allows for the synthesis of defect-free graphene oxide using a simpler procedure than traditional methods, enabling various industrial applications.
Researchers conducted the first controlled exposure clinical trial in humans using graphene oxide without adverse effects on lung or cardiovascular function. Further studies are needed to assess higher doses and longer exposures to determine safety.
Researchers developed sensors using aerogels to detect formaldehyde, a common indoor air pollutant, with real-time detection capabilities. The sensors require minimal power and can distinguish between different gases.
Researchers developed a UV-sensitive tape that can transfer 2D materials like graphene with ease, reducing damage and increasing efficiency. The new technology allows for flexible plastics to be used in device substrates, expanding potential applications.
Engineers developed an ultra-sensitive sensor made of graphene that can detect low concentrations of lead ions in water, achieving a record limit of detection down to the femtomolar range. The device's high sensitivity enables the detection of even one lead ion in a reasonable volume of water.
Researchers at Rice University have mapped the diffusion of graphene and hexagonal boron nitride in an aqueous solution, a crucial step towards larger-scale production of these 2D materials. The study found that the size of the material affects its movement speed, with hexagonal boron nitride moving faster than graphene.
Researchers at Tohoku University and Shanghai Jiao Tong University developed a machine learning method to predict the growth of carbon nanostructures on metal surfaces. The approach combines theoretical models with data from chemistry experiments to control the dynamics of material growth, leading to improved quality and efficiency.
Researchers at Rice University have discovered a graphene-derived material that can serve as a substitute for sand in concrete, offering a potential solution to the looming 'sand crisis.' The study found that the graphene-based concrete is 25% lighter but just as tough as conventional concrete.
Researchers developed a carbon-based tunable metasurface absorber with an ultrawide, tunable bandwidth in the THz range. The absorber boasts high absorption efficiency and insensitivity to polarization angles, paving the way for advanced technological applications.
Researchers at ETH Zurich have discovered a potential platform for spin qubits in bilayer graphene, with ultra-long-lived valley states. The study finds that the valley degree of freedom in BLG is associated with quantum states that can survive for over half a second.
A new transparent brain implant has been developed to read deep neural activity from the surface, providing a step closer to building a minimally invasive brain-computer interface. The technology enables high-resolution data about deep neural activity by using recordings from the brain surface and correlating them with calcium spikes i...
Scientists have directly imaged small noble gas clusters at room temperature, enabled by confining atoms between graphene layers. The discovery opens avenues for fundamental research and potential applications in quantum information technology.
Researchers have developed EGNITE, a novel class of flexible, high-resolution, high-precision graphene-based implantable neurotechnology. Preclinical studies demonstrated the technology's capacity to record high-fidelity neural signals and afford precise nerve modulation.
A team of researchers led by Walter de Heer at Georgia Institute of Technology has created a functional graphene semiconductor with 10 times the mobility of silicon. This breakthrough technology could enable smaller and faster devices, as well as applications for quantum computing.
Researchers at DOE's Pacific Northwest National Laboratory have discovered that adding a small amount of solid carbon to copper boosts its ability to conduct electricity. The findings could lead to more efficient electricity distribution, as well as more efficient motors for electric vehicles and industrial equipment.