The research team, which included Natalya Pugach from the Skobeltsyn Institute of Nuclear Physics, studied the interactions between superconductivity and magnetization in order to understand how to
control electron spins (electron magnetic moments) and to create the new generation of electronics.
«Physicists deploy magnetic vortex to
control electron spin: Potential technology for quantum computing, keener sensors.»
Not exact matches
«By twisting and
controlling the molecular bonds with light,» Awschalom says, «it is possible to operate on the
electron spins as they move through the chemical structure.»
In this configuration the lead forms «islands» below the graphene and the
electrons of this two - dimensional material behave as if in the presence of a colossal 80 - tesla magnetic field, which facilitates the selective
control of the flow of
spins.
The researchers» next goal is «to manipulate and
control a single
electron and its
spin on double - dot single -
electron devices by using asymmetric side-gate electrodes to demonstrate
spin qubits,» said Majima.
Researchers have demonstrated how to
control the «
electron spin» of a nanodiamond while it is levitated with lasers in a vacuum, an advance that could find applications in quantum information processing, sensors and studies into the fundamental physics of quantum mechanics.
«
Electron spin control: Levitated nanodiamond is research gem.»
A millimeter - scale antenna delivers microwaves to
control and flip the
electron spin, and a spectrometer detects these changes in
spin.
This is a schematic of an optical tweezer used in a vacuum chamber by Purdue University researchers, who
controlled the «
electron spin» of a levitated nanodiamond.
In the second paper in Nature Communications, Neupane and co-authors presented a model for
controlling the
spin direction of the
electron particles in a different material, bismuth selenide.
Here, we propose a dissipative scheme that achieves the preparation of pairs of nuclear
spins in long - lived singlet states by a protocol that combines the interaction between the nuclei and a periodically reset
electron spin of a nirogen - vacancy center with local radio - frequency
control of the nuclear
spins.
With our protocol one can detect, address and
control nuclear
spins around an
electron spin unambiguously and individually in a broad frequency band.
In close collaboration with our UNSW colleagues, we apply this method to the fabrication of quantum computer devices containing few or single atoms in which single
electron spins can be
controlled and read - out.