
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.
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.
Research on ammonia-oxidizing microorganisms reshapes scientists’ perspective on those microbes’ physiology and ecological niche.
Entangled photons reveal completely different information about an organic molecule than traditional spectroscopy techniques.
For the first time, researchers discovered magnetic order at high temperature in a metal widely used by the electronics industry.
Genetically modified bacteria brews two valuable products from underutilized plant fiber, potentially reducing fossil fuel use.
Researchers expand the quantum mechanical descriptions of nuclear fusion reactions.
Advanced electron microscopy and first principles calculations reveal atomic motifs at the oxidized surface of superconducting tantalum film.
In the unusual world of quantum materials, metals can guide light in their interiors instead of merely reflecting it.
Scientists create a genome-wide map of gene activity in bacteriophages.
Pseudomonas putida uses cheap plant biomass as a carbon source to make the precursor isoprenol.
Classical and quantum chips combine to simulate the collision of two neutrons on a present-day quantum computer.