9,078 research outputs found
Phase Transitions in the Early Universe
The physics of the 20th Century is governed by two pillars, Einstein's
relativity principle and the quantum principle. At the beginning of the 21st
Century, it becomes clear that there exist the smallest units of matter, such
as electrons, neutrinos, and quarks; their behaviors are described by the
Standard Model.
It was believed that the temperature of the early Universe was once 300 GeV,
or higher, at , and then going through the electroweak phase
transition. But the mass phase transition happens in the purely imaginary
temperature. Later on, its temperature was 150 MeV at ,
and then going through the "QCD cosmological phase transition". We attempt to
use the Standard Model, a completely dimensionless theory apart from the
negative "ignition" term, to conclude that the EW or mass phase transition {\it
does not exist}.
On the front of QCD cosmological phase transition, the intriguing question
about the latent heat (energy) is discussed and its role is speculated.Comment: 24 pages, 1 figur
Rattling and freezing in a 1-D transport model
We consider a heat conduction model introduced in \cite{Collet-Eckmann 2009}.
This is an open system in which particles exchange momentum with a row of
(fixed) scatterers. We assume simplified bath conditions throughout, and give a
qualitative description of the dynamics extrapolating from the case of a single
particle for which we have a fairly clear understanding. The main phenomenon
discussed is {\it freezing}, or the slowing down of particles with time. As
particle number is conserved, this means fewer collisions per unit time, and
less contact with the baths; in other words, the conductor becomes less
effective. Careful numerical documentation of freezing is provided, and a
theoretical explanation is proposed. Freezing being an extremely slow process,
however, the system behaves as though it is in a steady state for long
durations. Quantities such as energy and fluxes are studied, and are found to
have curious relationships with particle density
Variation of Entanglement Entropy in Scattering Process
In a scattering process, the final state is determined by an initial state
and an S-matrix. We focus on two-particle scattering processes and consider the
entanglement between these particles. For two types initial states; i.e., an
unentangled state and an entangled one, we calculate perturbatively the change
of entanglement entropy from the initial state to the final one. Then we show a
few examples in a field theory and in quantum mechanics.Comment: 13 pages; v2: refs. adde
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