349 research outputs found
Microcanonical Ensemble and Algebra of Conserved Generators for Generalized Quantum Dynamics
It has recently been shown, by application of statistical mechanical methods
to determine the canonical ensemble governing the equilibrium distribution of
operator initial values, that complex quantum field theory can emerge as a
statistical approximation to an underlying generalized quantum dynamics. This
result was obtained by an argument based on a Ward identity analogous to the
equipartition theorem of classical statistical mechanics. We construct here a
microcanonical ensemble which forms the basis of this canonical ensemble. This
construction enables us to define the microcanonical entropy and free energy of
the field configuration of the equilibrium distribution and to study the
stability of the canonical ensemble. We also study the algebraic structure of
the conserved generators from which the microcanonical and canonical ensembles
are constructed, and the flows they induce on the phase space.Comment: Plain TeX, 18 pages. Corrected report number onl
Spectral Function of Fermion Coupled with Massive Vector Boson at Finite Temperature in Gauge Invariant Formalism
We investigate spectral properties of a fermion coupled with a massive gauge
boson with a mass m at finite temperature (T) in the perturbation theory. The
massive gauge boson is introduced as a U(1) gauge boson in the Stueckelberg
formalism with a gauge parameter \alpha. We find that the fermion spectral
function has a three-peak structure for T \sim m irrespective of the choice of
the gauge parameter, while it tends to have one faint peak at the origin and
two peaks corresponding to the normal fermion and anti-plasmino excitations
familiar in QED in the hard thermal loop approximation for T \gg m. We show
that our formalism successfully describe the fermion spectral function in the
whole T region with the correct high-T limit except for the faint peak at the
origin, although some care is needed for choice of the gauge parameter for T
\gg m. We clarify that for T \sim m, the fermion pole is almost independent of
the gauge parameter in the one-loop order, while for T \gg m, the one-loop
analysis is valid only for \alpha \ll 1/g where g is the fermion-boson coupling
constant, implying that the one-loop analysis can not be valid for large gauge
parameters as in the unitary gauge.Comment: 28pages, 11figures. v2: typos fixe
Time-Shift in the OPERA set-up: proof against superluminal neutrinos without the need of knowing the CERN-LNGS distance and Reminiscences on the origin of the Gran Sasso Lab, of the 3rd neutrino and of the "Teramo Anomaly"
The LVD time stability allows to establish a time-shift in the OPERA
experiment, thus providing the first proof against Superluminal neutrinos,
using the horizontal muons of the "Teramo Anomaly". This proof is particularly
interesting since does not need the knowledge of the distance between the place
where the neutrinos are produced (CERN) and the place where they are detected
(LNGS). Since the Superluminal neutrinos generated in the physics community a
vivid interest in good and bad behaviour in physics research, the author
thought it was appropriate to recall the origin of the Gran Sasso Lab, of the
3rd neutrino, of the horizontal muons due to the "Teramo Anomaly" and of the
oscillation between leptonic flavours, when the CERN-Gran Sasso neutrino beam
was included in the project for the most powerful underground Laboratory in the
world.Comment: 35 pages, 25 Figures, Invited paper at the Gran Sasso mini-Workshop
on LNGS results on the neutrino velocity topic, Gran Sasso, Italy, 28 March
201
Non-Trivial Ghosts and Second Class Constraints
In a model in which a vector gauge field is coupled to an
antisymmetric tensor field possessing a pseudoscalar mass, it
has been shown that all physical degrees of freedom reside in the vector field.
Upon quantizing this model using the Faddeev-Popov procedure, explicit
calculation of the two-point functions at one-loop
order seems to have yielded the puzzling result that the effective action
generated by radiative effects has more physical degrees of freedom than the
original classical action. In this paper we point out that this is not in fact
a real effect, but rather appears to be a consequence of having ignored a
"ghost" field arising from the contribution to the measure in the path integral
arising from the presence of non-trivial second-class constraints. These ghost
fields couple to the fields and , which makes them
distinct from other models involving ghosts arising from second-class
constraints (such as massive Yang-Mills (YM) models) that have been considered,
as in these other models such ghosts decouple. As an alternative to dealing
with second class constraints, we consider introducing a "Stueckelberg field"
to eliminate second-class constraints in favour of first-class constraints and
examine if it is possible to then use the Faddeev-Popov quantization procedure.
In the Proca model, introduction of the Stueckelberg vector is equivalent to
the Batalin-Fradkin-Tyutin (BFT) approach to converting second-class
constraints to being first class through the introduction of new variables.
However, introduction of a Stueckelberg vector is not equivalent to the BFT
approach for the vector-tensor model. In an appendix, the BFT procedure is
applied to the pure tensor model and a novel gauge invariance is found.Comment: 23 pages, LaTeX2e forma
Geometrical approach to the proton spin decomposition
We discuss in detail and from the geometrical point of view the issues of
gauge invariance and Lorentz covariance raised by the approach proposed
recently by Chen et al. to the proton spin decomposition. We show that the
gauge invariance of this approach follows from a mechanism similar to the one
used in the famous Stueckelberg trick. Stressing the fact that the Lorentz
symmetry does not force the gauge potential to transform as a Lorentz
four-vector, we show that the Chen et al. approach is Lorentz covariant
provided that one uses the suitable Lorentz transformation law. We also make an
attempt to summarize the present situation concerning the proton spin
decomposition. We argue that the ongoing debates concern essentially the
physical interpretation and are due to the plurality of the adopted pictures.
We discuss these different pictures and propose a pragmatic point of view.Comment: 39 pages, 1 figure, updated version to appear in PRD (2013
A Chiral Spin Theory in the Framework of an Invariant Evolution Parameter Formalism
We present a formulation for the construction of first order equations which
describe particles with spin, in the context of a manifestly covariant
relativistic theory governed by an invariant evolution parameter; one obtains a
consistent quantized formalism dealing with off-shell particles with spin. Our
basic requirement is that the second order equation in the theory is of the
Schr\"{o}dinger-Stueckelberg type, which exhibits features of both the
Klein-Gordon and Schr\"{o}dinger equations. This requirement restricts the
structure of the first order equation, in particular, to a chiral form. One
thus obtains, in a natural way, a theory of chiral form for massive particles,
which may contain both left and right chiralities, or just one of them. We
observe that by iterating the first order system, we are able to obtain second
order forms containing the transverse and longitudinal momentum relative to a
time-like vector used to maintain covariance of the theory.
This time-like vector coincides with the one used by Horwitz, Piron, and Reuse
to obtain an invariant positive definite space-time scalar product, which
permits the construction of an induced representation for states of a particle
with spin. We discuss the currents and continuity equations, and show that
these equations of motion and their currents are closely related to the spin
and convection parts of the Gordon decomposition of the Dirac current. The
transverse and longitudinal aspects of the particle are complementary, and can
be treated in a unified manner using a tensor product Hilbert space.
Introducing the electromagnetic field we find an equation which gives rise to
the correct gyromagnetic ratio, and is fully Hermitian under the proposed
scalar product. Finally, we show that the original structure of Dirac'sComment: Latex, 61 pages. Minor revisions. To be published in J. Math. Phy
The Supersymmetric Stueckelberg Mass and Overcoming the Fayet-Iliopoulos Mechanism for Breaking Symmetry
Gauge invariant generation of mass for supersymmetric U(1) vector field
through use of a chiral Stueckelberg superfield is considered. When a
Fayet-Iliopoulos D term is also present, no breaking of supersymmetry ever
occurs so long as the Stueckelberg mass is not zero. A moduli space in which
gauge symmetry is spontaneously broken arises in this case
LHC signatures for Z` models with continuously distributed mass
We discuss phenomenological consequences of renormalizable Z` models with
continuously distributed mass. We point out that one of possible LHC signatures
for such nodel is the existence of broad resonance in Drell-Yan reaction .Comment: 7 page
Quantum dynamics of a nanomagnet in a rotating field
Quantum dynamics of a two-state spin system in a rotating magnetic field has
been studied. Analytical and numerical results for the transition probability
have been obtained along the lines of the Landau-Zener-Stueckelberg theory. The
effect of various kinds of noise on the evolution of the system has been
analyzed.Comment: 7 pages, 7 figure
A Supersymmetric U(1)' Model with Multiple Dark Matters
We consider a scenario where a supersymmetric model has multiple dark matter
particles. Adding a U(1)' gauge symmetry is a well-motivated extension of the
Minimal Supersymmetric Standard Model (MSSM). It can cure the problems of the
MSSM such as the mu-problem or the proton decay problem with high-dimensional
lepton number and baryon number violating operators which R-parity allows. An
extra parity (U-parity) may arise as a residual discrete symmetry after U(1)'
gauge symmetry is spontaneously broken. The Lightest U-parity Particle (LUP) is
stable under the new parity becoming a new dark matter candidate. Up to three
massive particles can be stable in the presence of the R-parity and the
U-parity. We numerically illustrate that multiple stable particles in our model
can satisfy both constraints from the relic density and the direct detection,
thus providing a specific scenario where a supersymmetric model has
well-motivated multiple dark matters consistent with experimental constraints.
The scenario provides new possibilities in the present and upcoming dark matter
searches in the direct detection and collider experiments.Comment: 25 pages, 5 figure
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