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

Illustration showing a crystal structure, with balls connected by lines and a blue ball increasing in size moving above the structure

Thin Materials and Fat Electrons: A Recipe for New Quantum Phenomena

The 2D material cerium silicon iodide contains the same heavy electrons responsible for heavy fermion physics, something so far seen only in 3D materials.

Applying a voltage to lanthanum strontium manganite (LSMO) can cause it to separate into distinct regions with dramatically different magnetic properties, as illustrated by the red and blue colors in the above figure.

Tuning Magnetism With Voltage Opens a New Path to Neuromorphic Circuits

Experiments show that applied voltage can dramatically alter the magnetic properties of quantum materials.

A metallic line atop a medium biased at the edge of chaos can provide effective negative resistance for time-varying signals, outputting a larger signal compared to its input. The energy for amplification comes from the static bias applied to the medium.

The “Edge of Chaos” Amplifies Signals Without Transistors

Emulating the edge of chaos of axons enables a metal wire to overcome its resistance without cooling, thereby amplifying signals flowing inside of it.

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.

Advanced Computing Brings Autonomous Investigations to Nanostructured Surfaces

Machine learning and artificial intelligence accelerate nanomaterials investigations.

Ultrathin Crystals Vibe with Infrared Light

Crystalline nanoribbons synthesized to resonate with infrared light for imaging, sensing, and signaling pass a crucial test.

Perovskite Stability and Solar Conversion Performance Improve in Materials with Less Bromide Migration

Researchers find a way to improve the stability of hybrid organic-inorganic crystals called mixed halide-perovskites, a promising material for solar cells.