Plasma is a hot, energetic gas where the atoms are stripped of their electrons, creating an electrically active gas with
unique magnetic properties.
The research was supported by the U.S. Department of Energy's ARPA - E REACT program (Advanced Research Projects Agency - Energy — Rare Earth Alternatives in Critical Technologies) which develops cost - effective alternatives to rare earths, the naturally occurring minerals with
unique magnetic properties that are used in electric vehicle (EV) motors, and wind generators.
Not exact matches
The
unique structure translates to thermal, electrical and
magnetic properties no other material can match, and the commercial applications are almost limitless.
The oxide superconductors, particularly those recently discovered that are based on La2CuO4, have a set of peculiarities that suggest a common,
unique mechanism: they tend in every case to occur near a metal - insulator transition into an odd - electron insulator with peculiar
magnetic properties.
These «multiferroic» materials absorb solar radiation and possess
unique electrical and
magnetic properties.
A
unique property of the molecule is the large permanent dipole moment, which reacts with an electric field much like a bar magnet reacts with a
magnetic field.
Their
unique optical and
magnetic properties are used in various high - tech applications, such as motors, catalysts, light - emitting diodes and batteries.
Using the new data from the research teams on the West Coast, Eisenbach and Kent were able to precisely model the measured atomic structure, including defects, from a
unique iron - platinum (FePt) nanoparticle and simulate its
magnetic properties on the 27 - petaflop Titan supercomputer at the OLCF.
The
magnetic field compresses the metamaterial, but does not constrain it, enabling an acoustic or mechanical wave to perturb the material and generate
unique properties, including negative modulus and negative density that blocks sound waves and mechanical vibrations of certain frequencies from passing through.