Researchers at the University of Manchester have demonstrated that laser could be used to cool graphene by stacking special graphene sheets in a specific manner. This would help cool graphene electronic devices allowing it to run faster, with better performance.
Scientists at Rice University lab have modified graphene nanoribbon deicing film designed for radar domes to now suit applications on glass. This technology may help keep glass surfaces of automobile windshields, large buildings and other similar applications, free from ice formation, while remaining transparent to radio frequencies.
Chalmers researchers have demonstrated the possibility of communicating with an atom using sound. They have successfully coupled acoustic waves to an artificial atom.
Researchers from the Stanford Institute for Materials & Energy Sciences and the SLAC National Accelerator Laboratory are challenging the prevailing view that the rapid charging and draining of lithium ion batteries is damaging and have discovered a new way to think about battery degradation.
Researchers from the University of Vienna have used single-layer graphene with silicon atoms embedded into its lattice in order to study the manipulation of single atoms.
A team of researchers from Texas A&M University have revealed the work-hardening and plasticity properties of twinned aluminium with incoherent twin boundaries using an in situ nanoindentation technique.
Researchers at the University of Manchester have discovered that graphene paint, which is a solution of graphene oxide, could provide a non-corrosive, chemically resistant, and impermeable coating for applications in a wide range of industries.
Solids demonstrate unusual properties at the nanoscale. Scientists at Caltech have utilized this property to construct new materials with 3D ceramic nanolattices.
Excitonic dark states in single atomic layers of tungsten disulfide have been revealed by a Berkeley Lab research team using two-photon excitation spectroscopy, uncovering the reason for the exotic optoelectronic properties of monolayers of transition metal dichalcogenide (TMDC) materials.
Researchers from the University of Texas (UT), Arlington have developed a new technique of cooling electrons to temperatures as low as -228°C at ambient conditions, without external cooling.
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