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We stand at the forefront of quantum materials. Understanding quantum phenomena in materials holds the potential for the next technological revolution in information devices and computing.
We continue a more than 70-year reputation of excellence in science with rare earths.
Our research pursues the fundamental knowledge to control and manipulated chemical processes at complex interfaces including understanding how solvents affect chemical reactions and how molecules d
Homogeneous and Interfacial Catalysis in 3D Controlled Environments
γ-irradiation induced the formation of stable radicals that were used to polarize 29Si and 1H spins in inorganic and organic solids by dynamic nuclear polarization (DNP). γ-irradiation will enable magic angle spinning (MAS) DNP experiments on previously inaccessible non-porous inorganic solids and insoluble polymers.
Georgiy Akopov, a postdoctoral research associate at the U.S. Department of Energy’s Ames Laboratory, has won a Young Investigator Award from the American Chemical Society Division of Inorganic Chemistry.
Topology-protected charge transport on surfaces of three-dimensional topological insulators (TIs) is breaking new ground in quantum science and technology.
We have developed and validated a model which predicts size-independent shapes of metal nanoparticles that are supported on a solid surface and blanketed by a two-dimensional material such as graphene.
Lattice instability criterion is linear in stresses for any stress state in a material.
Understanding the link between magnetism and unconventional superconductivity remains a grand challenge in quantum materials. Significant progress gaining deeper insight into this challenge has been made via the first observation of a quantum criticality (QC) with a hedgehog spin-vortex crystal antiferromagnetic state.