1,929 research outputs found
"Dark" Z implications for Parity Violation, Rare Meson Decays, and Higgs Physics
General consequences of mass mixing between the ordinary Z boson and a
relatively light Z_d boson, the "dark" Z, arising from a U(1)_d gauge symmetry,
associated with a hidden sector such as dark matter, are examined. New effects
beyond kinetic mixing are emphasized. Z-Z_d mixing introduces a new source of
low energy parity violation well explored by possible future atomic parity
violation and planned polarized electron scattering experiments. Rare K (B)
meson decays into pi (K) l^+ l^- (l = e, mu) and pi (K) nu anti-nu are found to
already place tight constraints on the size of Z-Z_d mixing. Those
sensitivities can be further improved with future dedicated searches at K and B
factories as well as binned studies of existing data. Z-Z_d mixing can also
lead to the Higgs decay H -> Z Z_d, followed by Z -> l_1^+ l_1^- and Z_d ->
l_2^+ l_2^- or "missing energy", providing a potential hidden sector discovery
channel at the LHC. An illustrative realization of these effects in a 2 Higgs
doublet model is presented.Comment: Version to appear in PR
Electroweak higher-order effects and theoretical uncertainties in deep-inelastic neutrino scattering
A previous calculation of electroweak O(alpha) corrections to deep-inelastic
neutrino scattering, as e.g. measured by NuTeV and NOMAD, is supplemented by
higher-order effects. In detail, we take into account universal two-loop
effects from \Delta\alpha and \Delta\rho as well as higher-order final-state
photon radiation off muons in the structure function approach. Moreover, we
make use of the recently released O(alpha)-improved parton distributions
MRST2004QED and identify the relevant QED factorization scheme, which is DIS
like. As a technical byproduct, we describe slicing and subtraction techniques
for an efficient calculation of a new type of real corrections that are induced
by the generated photon distribution. A numerical discussion of the
higher-order effects suggests that the remaining theoretical uncertainty from
unknown electroweak corrections is dominated by non-universal two-loop effects
and is of the order 0.0003 when translated into a shift in
sin^2\theta_W=1-MW^2/MZ^2. The O(alpha) corrections implicitly included in the
parton distributions lead to a shift of about 0.0004.Comment: 25 pages, latex, 8 postscript figure
The Physical Meaning of the Holographic Principle
We show in this pedagogical review that far from being an apparent law of physics that stands by itself, the holographic principle is a straightforward consequence of the quantum information theory of separable systems. It provides a basis for the theories of measurement, time, and scattering. Utilizing the notion of holographic screens, which are information encoding boundaries between physical subsystems, we demonstrate that the physical interaction is an information exchange during which information is strictly conserved. Then we use generalized holographic principle in order to flesh out a fully-general quantum theory of measurement in which the measurement produces finite-resolution, classical outcomes. Further, we show that the measurements are given meaning by quantum reference frames and sequential measurements induce topological quantum field theories. Finally, we discuss principles equivalent to the holographic principle, including Markov blankets and the free-energy principle in biology, multiple realizability and virtual machines in computer science, and active inference and interface theories in cognitive science. This appearance in multiple disciplines suggests that the holographic principle is not just a fundamental principle of physics, but of all of science.Quanta 2022; 11: 72–96
Communication protocols and quantum error-correcting codes from the perspective of topological quantum field theory
Topological quantum field theories (TQFTs) provide a general,
minimal-assumption language for describing quantum-state preparation and
measurement. They therefore provide a general language in which to express
multi-agent communication protocols, e.g. local operations, classical
communication (LOCC) protocols. Here we construct LOCC protocols using TQFT,
and show that LOCC protocols induce quantum error-correcting codes (QECCs) on
the agent-environment boundary. Such QECCs can be regarded as implementing, or
inducing the emergence of, spacetimes on such boundaries. We investigate this
connection between inter-agent communication and spacetime using BF and
Chern-Simons theories, and then using topological M-theory.Comment: 52 page
Model-dependent radiative corrections to tau- -> pi- pi0 nu revisited
The long-distance electromagnetic radiative corrections to tau- -> pi- pi0 nu
are re-evaluated. A meson dominance model is used to describe the emission of
real photons in this decay. Results obtained for the hadronic spectrum and the
decay rate in photon inclusive reactions are compared with previous
calculations based on the chiral resonance theory. Independent tests in tau ->
pi pi nu gamma that can help to validate the predictions of one of the two
models are briefly discussed.Comment: 5 pages, 4 figures, talk given by GLC at the 9th International
Workshop on Tau Lepton Physics, Pisa (Italy), september 200
Effects from the charm scale in K+ -> pi+ nu nubar
We consider contributions to the rare decay K+ -> pi+ nu nubar which become
nonlocal at the charm scale. Compared to the leading term, such amplitudes are
suppressed by two powers of mK/mc and could potentially give corrections at the
level of 15%. We compute the leading coefficients of the subleading dimension
eight operators in the effective theory below the charm mass. The matrix
elements of these operators cannot all be calculated from first principles and
some must be modeled. We find that these contributions are likely to be small,
but the estimate is sufficiently uncertain that the result may be as large as
the existing theoretical uncertainty from other sources.Comment: 9 pages, 3 figures; Eq. (15) fixed, all results and conclusions
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