New Mechanism Explains Rapid Energy Sharing Across Atomic Semiconductor Junctions
Electron transfer between atomically thin materials triggers the ultrafast release of heat.
Electron transfer between atomically thin materials triggers the ultrafast release of heat.
Scientists learn how to manipulate quantum properties in graphene to create resistance-free, electricity channels for loss-free future electronics.
Synchrotron X-ray spectroscopy allows atom-level examination of iron and terbium atoms.
Two types of superconductivity compete at the edge between a topological semimetal and a conventional metal, causing the electrons to switch behavior erratically.
By using a small number of photons to process information, two-dimensional quantum materials can lead to secure, energy-efficient communications.
Scientists discover that superconductivity in copper-based materials is linked with fluctuations of ordered electric charge and mobility of vortex matter.
Scientists develop a nanoscale electron imaging method that reveals the dynamics of the collective vibrations of atoms at the interface between materials.
Twisted bilayer graphene defies conventional theories by exhibiting superconductivity despite a vanishingly small charge carrier velocity.
Theory uncovers the formation process and dynamics of atomic-scale defects for generating and controlling qubits for quantum computers and sensors.
Electric fields in a crystal of Ni2Mo3O8 create spin excitons and elusive magnetic order.
For the first time, researchers discovered magnetic order at high temperature in a metal widely used by the electronics industry.
In the unusual world of quantum materials, metals can guide light in their interiors instead of merely reflecting it.