313 research outputs found
Spin Hydrodynamic Generation in the Charged Subatomic Swirl
Recently there have been significant interests in the spin hydrodynamic
generation phenomenon from multiple disciplines of physics. Such phenomenon
arises from global polarization effect of microscopic spin by macroscopic fluid
rotation and is expected to occur in the hot quark-gluon fluid (the ``subatomic
swirl'') created in relativistic nuclear collisions. This was indeed discovered
in experiments which however revealed an intriguing puzzle: a polarization
difference between particles and anti-particles. We suggest a novel application
of a general connection between rotation and magnetic field: a magnetic field
naturally arises along the fluid vorticity in the charged subatomic swirl. We
establish this mechanism as a new way for generating long-lived in-medium
magnetic field in heavy ion collisions. Due to its novel feature, this new
magnetic field provides a nontrivial explanation to the puzzling observation of
a difference in spin hydrodynamic generation for particles and anti-particles
in heavy ion collisions.Comment: 10 pages, 3 figures, title changed according to published versio
Magnetic Field Effect on Charmonium Production in High Energy Nuclear Collisions
It is important to understand the strong external magnetic field generated at
the very beginning of high energy nuclear collisions. We study the effect of
the magnetic field on the charmonium yield and anisotropic distribution in
Pb+Pb collisions at the LHC energy. The time dependent Schr\"odinger equation
is employed to describe the motion of pairs. We compare our model
prediction of non- collective anisotropic parameter of s with CMS
data at high transverse momentum. This is the first attempt to measure the
magnetic field in high energy nuclear collisions.Comment: 5 pages, 4 figure
Tripartite Entanglement and Quantum Correlation
We provide an analytical solution from the correlators of the generalized
-matrix in the 3-qubit pure states. It provides the upper bound to the
maximum violation of Mermin's inequality. For a generic 2-qubit pure state, the
concurrence characterizes the maximum violation of Bell's inequality from the
-matrix. Therefore, people expect that the maximum violation should be
proper to quantify Quantum Entanglement. The -matrix shows the maximum
violation of Bell's operator. For a general 3-qubit state, we have five
invariant entanglement quantities under local unitary transformations. We show
that the five invariant quantities describe the correlation in the generalized
-matrix. The violation of Mermin's operator is not a proper diagnosis by
observing the dependence for entanglement measures. We then classify 3-qubit
quantum states. Each classification quantifies Quantum Entanglement by the
total concurrence. In the end, we relate the experiment correlators to Quantum
Entanglement.Comment: 14 pages, 4 figures, minor changes, reference change
Non-LocalityQuantum Entanglement
The unique entanglement measure is concurrence in a 2-qubit pure state. The
maximum violation of Bell's inequality is monotonically increasing for this
quantity. Therefore, people expect that pure state entanglement is relevant to
the non-locality. For justification, we extend the study to three qubits. We
consider all possible 3-qubit operators with a symmetric permutation. When only
considering one entanglement measure, the numerical result contradicts
expectation. Therefore, we conclude ``Non-LocalityQuantum Entanglement''.
We propose the generalized -matrix or correlation matrix for the new
diagnosis of Quantum Entanglement. We then demonstrate the evidence by
restoring the monotonically increasing result.Comment: 38 pages, 10 figures, minor changes, reference adde
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