MSE Science Highlights | U.S. DOE Office of Science (SC)

Color map of the differential conductance as a function of increasing magnetic field (x axis) in niobium deposited on 2D molybdenum ditelluride (MoTe2). The red spikes are oscillations of the MoTe2 edge supercurrent due to magnetic field flux.

Superconductivity Is Unpredictable at the Edge

Two types of superconductivity compete at the edge between a topological semimetal and a conventional metal, causing the electrons to switch behavior erratically.

A laser creates pairs of positive and negative charges bound together (large blue and red spheres) in a device made of three atomically thin layers (sheets of metallic red and green spheres). The charge pairs change the properties of the laser beam (red).

The Future of Telecom Is Atomically Thin

By using a small number of photons to process information, two-dimensional quantum materials can lead to secure, energy-efficient communications.

Researchers combined high magnetic fields with X-ray scattering to reveal the connection between superconducting vortices (black circles), charge density waves (red wiggles), and spin density waves (blue wiggles) in a cuprate superconductor.

What Makes High Temperature Superconductivity Possible? Researchers Get Closer to a Unified Theory

Scientists discover that superconductivity in copper-based materials is linked with fluctuations of ordered electric charge and mobility of vortex matter.

Left: A beam of electrons generates vibrational waves in a crystal lattice that are then reflected by quantum dots. Right: Generated vibrations are more easily reflected by abrupt, sharp interfaces of materials than by diffuse ones.

Unveiling How Heat Moves in Materials with Atomic-Scale Resolution

Scientists develop a nanoscale electron imaging method that reveals the dynamics of the collective vibrations of atoms at the interface between materials.

Map of resistivity as a function of the charge carrier density (x axis) and current density (y axis) in bilayer graphene. Superconductivity occurs in the dark blue region in the bottom graph and is turned off by a magnetic field (upper graph).

Quantum Effects Make Electrons Superconduct while Standing Still

Twisted bilayer graphene defies conventional theories by exhibiting superconductivity despite a vanishingly small charge carrier velocity.

Artist’s representation of the formation pathway of vacancy complexes for spin-based qubits in in the silicon carbide host lattice and to the right the associated energy landscape.

Scientists Tame Quantum Bits in a Widely Used Semiconductor Material

Theory uncovers the formation process and dynamics of atomic-scale defects for generating and controlling qubits for quantum computers and sensors.

Left: Nickel ions in Ni2Mo3O8 (spheres inside center of polygons) form a honeycomb lattice of tetrahedral (green) and octahedral (blue) polygons. Right: Excitations of the magnetism from the tetrahedral polygons form a neutron scattering pattern (orange).

What If a Nonmagnetic Material Could Be Magnetic?

Electric fields in a crystal of Ni2Mo3O8 create spin excitons and elusive magnetic order.

Depiction of the newly discovered magnetic order of nickel spins (arrows) in nickel monosilicide as revealed by neutron diffraction (background) for the two sites of nickel (spheres).

A Surprising Discovery: Magnetism in a Common Material for Microelectronics

For the first time, researchers discovered magnetic order at high temperature in a metal widely used by the electronics industry.

Infrared laser light (red beam) illuminates the surface of ZrSiSe and mixes with electron oscillations enabled by an atomic force microscope (silver cone), propagating light as ray-like structures that guide the light through the interior (blue zig-zag).

What If Metals Could Conduct Light?

In the unusual world of quantum materials, metals can guide light in their interiors instead of merely reflecting it.

Water-soluble and oil-soluble organic molecules effectively separate different elements in the lanthanide series of the Periodic Table.

“Tug of War” Tactic Enhances Chemical Separations for Critical Materials

Opposing teams of water-loving and oil-loving molecules separate metals called lanthanides that are important in developing clean energy technologies.

Researchers Test Quantum Theory with Precision-Engineered Thin Films

Scientists can now verify theoretical predictions using one-dimensional compositions grown in-situ at a synchrotron spectroscopy station.

X-ray Spectral Microscopy Reveals The Active Edges of a Water-Splitting Material

X-rays penetrate a working electrode to determine the structure and chemistry in play when water enters the electrochemically active layers.