Defect-enhanced transport and complex phase growth are changing design rules for lithium-ion batteries.
Simulations discovered the first molecule with three extra electrons and extraordinary stability.
The magnetic noise caused by adsorbed oxygen molecules is “eating at” the phase stability of quantum bits, mitigating the noise is vital for future quantum computers.
Large-scale simulations of quarks promise precise view of reactions of astrophysical importance.
Gravitational wave observations combined with optical and gamma-ray data confirm earlier predictions, offer insights into how the galaxy produces lead, mercury, and other elements.
For one of the strongest known materials, calculations clarify a long-standing debate about how atoms pack together.
Theory predicts that bending a film will control spin direction and create a spin current for next-generation electronics.
Readily rotating molecules let electrons last, resulting in higher solar cell efficiency.
Novel spin-polarized surface states may guide the search for materials that host Majorana fermions, unusual particles that act as their own antimatter, and could revolutionize quantum computers.
Built from the bottom up, nanoribbons can be semiconducting, enabling broad electronic applications.
New materials could turn water into the fuel of the future.
Neutrons provide the solution to nanoscale examination of living cell membrane and confirm the existence of lipid rafts.
