Chiral Asymmetry Creates a Path to High-Efficiency Future Electronics
Scientists learn how to manipulate quantum properties in graphene to create resistance-free, electricity channels for loss-free future electronics.
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.
Spatial transcriptomics, combined with single-cell expression profiling, reveals new information on plant/arbuscular mycorrhizal interactions.
Years of basic scientific research crosscutting multiple disciplines produces new information on the nanoscale complexities of shale.
By achieving very high density and confinement quality at the same time, researchers make new strides toward fusion energy.
Scientists examine how molecular systems made of nanocrystals and proteins support the production of ammonia using light.
A new calculation helps scientists understand how matter formed out of the hot, dense soup of subatomic particles created by the Big Bang.
Researchers find that the quantum flavor and momentum states of the neutrinos in a supernova are strongly entangled through frequent interactions.
Simulations of massive neutron star merger remnants reveal their structure and early evolution as they cool down by emitting neutrinos.
Leveraging a new genome annotation tool, researchers identified ‘talented’ microorganisms with genes for transforming polyphenols in peatlands.
New calculations confirm recent experimental results on the transition between the alpha particle and its first excited state.