More Steps, Faster Results
New method lets supercomputers model key details of greenhouse gases and molecules relevant to automobile combustion.
New method lets supercomputers model key details of greenhouse gases and molecules relevant to automobile combustion.
Researchers simulate the design of new quantum bits for easier engineering of quantum computers.
Bombarding a material with high-energy charged atoms heals, rather than damages, the atomic structure, which could lead to longer-lasting components for extreme environments.
Self-healing diamond-like carbon coating could revolutionize lubrication.
Scientists seek to improve the battery by investigating the detailed interactions lithium ions experience with liquid battery electrolytes.
Research uncovers the errors that prevent modeled precipitation variations from matching real-world results.
New approach could benefit applications as diverse as propeller and printers.
First atomically thin, halide perovskite sheets could be an alternative to graphene for future electronics.
Microporous polymer separator prevents specific molecules from crossing battery and causing degradation and shorter lifetimes.
Novel self-assembly can tune the electronic properties of graphene, possibly opening doors for tiny, powerful electronic devices.
Materials based on clusters of atoms called “super-ions” may revolutionize the whole solar cell industry.
Scientists apprehended the atomic-scale, microscopic mechanism that limits light emission in LED lighting.