But
because electron spins offer one of the most promising models for quantum bitsphysical states that can store far more information than conventional computer bitsscientists have sought ways around the coherence problem.
Not exact matches
Then for the bizarre part: Atom C,
because it was previously entangled with B, became imprinted with atom A's information — in this case, a pattern in the
spin of its
electrons.
Neutrons are ideal tools for identifying and characterizing magnetism in almost any material,
because they, like
electrons, exhibit a flow of magnetism called «
spin.»
The three
spins must coordinate their orientations
because it cost extra energy to put
electrons with the same
spin into the same box.
Because an EDM would cause an
electron — or, more precisely, its
spin axis — to rotate when placed in an electric field, simply sticking an
electron between positive and negative electrodes should reveal it, in principle.
Cornell's group hasn't yet improved on the best existing measurement of the
electron's sphericity,
because the grouped ions disturb each other's
spin and limit the number the trap can contain.
They are said to be «entangled»
because, in the bizarre world of quantum mechanics, neither
electron has a definite
spin until one of them is measured.
That's
because the recipe exploits the fact that the black hole conserves angular momentum, so that its final
spin is equal to its initial
spin plus that of the
electron.
Some materials are magnetic
because of the behavior of the
spins of their
electrons.
Because each atom's magnetism originates from the
spin of an unpaired
electron within it, models of how magnetism arises are known as
spin models.
The group did not have to look far to find its spintronic memory,
because although the
spin of a phosphorus donor
electron has a short lifetime, the
spin of the phosphorus nucleus is rather robust.
This occurred
because the gold
electrons changed their
spin magnetic moments to neutralize the molecule's moment, something they didn't quite succeed in, and therefore long - range magnetic order was formed.
Short - range
spin -
spin interactions happen all the time: Magnets stick to the fridge
because the
electrons in the magnet and those in the fridge's steel exterior are all
spinning around in the same direction.
That's
because in the excited state, two
electrons waltz through the molecule,
spinning like tops, and only when the
electron spins point in opposite directions does the dance end with the release of a photon.
This last property is of interest for the development of new magnetic memory devices,
because the
spin of the
electron can be used to store and transfer information.