6,096 research outputs found
On Resonant Leptogenesis
It has been recently shown that the quantum Boltzmann equations may be
relevant for the leptogenesis scenario. In particular, they lead to a
time-dependent CP asymmetry which depends upon the previous dynamics of the
system. This memory effect in the CP asymmetry is particularly important in
resonant leptogenesis where the asymmetry is generated by the decays of nearly
mass-degenerate right-handed neutrinos. We study the impact of the nontrivial
time evolution of the CP asymmetry in resonant leptogenesis, both in the
one-flavour case and with flavour effects included. We show that significant
qualitative and quantitative differences arise with respect to the case in
which the time dependence of the CP asymmetry is neglected.Comment: 16 pages, 7 figures. IOP LaTeX class used. Minor corrections and
references added. Matches the version published in JCA
On the Impact of Flavour Oscillations in Leptogenesis
When lepton flavour effects in thermal leptogenesis are active, they
introduce important differences with respect to the case in which they are
neglected, the so-called one-flavour approximation. We investigate analytically
and numerically the transition from the one-flavour to the two-flavour case
when the -lepton flavour becomes distinguishable from the other two
flavours. We study the impact of the oscillations of the asymmetries in lepton
flavour space on the final lepton asymmetries, for the hierarchical
right-handed neutrino mass spectrum. Flavour oscillations project the lepton
state on the flavour basis very efficiently. We conclude that flavour effects
are relevant typically for M_1\lsim 10^{12} GeV, where is the mass of
the lightest right-handed neutrino.Comment: 24 pages, 9 figures. Minor corrections; version published in JCA
Quantum Boltzmann Equations and Leptogenesis
The closed time-path formalism is a powerful Green's function formulation to
describe non-equilibrium phenomena in field theory and it leads to a complete
non-equilibrium quantum kinetic theory. We make use of this formalism to write
down the set of quantum Boltzmann equations relevant for leptogenesis. They
manifest memory effects and off-shell corrections. In particular, memory
effects lead to a time-dependent CP asymmetry whose value at a given instant of
time depends upon the previous history of the system. This result is
particularly relevant when the asymmetry is generated by the decays of nearly
mass-degenerate heavy states, as in resonant or soft leptogenesis.Comment: 21 pages, 5 figures. IOP LaTeX class used. Minor corrections and
references added. Matches the version published in JCA
One numerical procedure for two risk factors modeling
We propose a numerical procedure for the pricing of financial contracts whose contingent claims are exposed to two sources of risk: the stock price and the short interest rate. More precisely, in our pricing framework we assume that the stock price dynamics is described by the Cox, Ross Rubinstein (CRR, 1979) binomial model under a stochastic risk free rate, whose dynamics evolves over time accordingly to the Black, Derman and Toy (BDT, 1990) one-factor model. To this aim, we set the hypothesis that the instantaneous correlation between the trajectories of the future stock price (conditional on the current value of the short rate) and of the future short rate is zero. We then apply the resulting stock price dynamics to evaluate the price of a simple contract, i.e. of a stock option. Finally, we compare the derived price to the price of the same option under different pricing models, as the traditional Black and Scholes (1973) model. We expect that, the difference in the two prices is not sensibly large. We conclude showing in which cases it should be helpful to adopt the described model for pricing purposes.option pricing; stochastic short rate model; binomial tree
Automatic Mode Switching in Atrial Fibrillation
Automatic mode switching (AMS) algorithms were designed to prevent tracking of atrial tachyarrhythmias (ATA) or other rapidly occurring signals sensed by atrial channels, thereby reducing the adverse hemodynamic and symptomatic consequences of a rapid ventricular response. The inclusion of an AMS function in most dual chamber pacemaker now provides optimal management of atrial arrhythmias and allows the benefit of atrioventricular synchrony to be extended to a population with existing atrial fibrillation. Appropriate AMS depends on several parameters: a) the programmed parameters; b) the characteristics of the arrhythmia; c) the characteristics of the AMS algorithm. Three qualifying aspects constitute an AMS algorithm: onset, AMS response, and resynchronization. Since AMS programs also provide data on the time of onset and duration of AMS episodes, AMS data may be interpreted as a surrogate marker of ATAs recurrence. Recently, stored electrograms corresponding to episodes of ATAs have been introduced, thus clarifying the accuracy of AMS in detecting ATAs Clinically this information may be used to assess the efficacy of an antiarrhythmic intervention or the risk of thromboembolic events, and it may serve as a valuable research tool for evaluating the natural history and burden of ATAs
Estimating packet loss rate in the access through application-level measurements
End user monitoring of quality of experience is one of the necessary steps to achieve an effective and winning control over network neutrality. The involvement of the end user, however, requires the development of light and user-friendly tools that can be easily run at the application level with limited effort and network resources usage. In this paper, we propose a simple model to estimate packet loss rate perceived by a connection, by round trip time and TCP goodput samples collected at the application level. The model is derived from the well-known Mathis equation, which predicts the bandwidth of a steady-state TCP connection under random losses and delayed ACKs and it is evaluated in a testbed environment under a wide range of different conditions. Experiments are also run on real access networks. We plan to use the model to analyze the results collected by the "network neutrality bot" (Neubot), a research tool that performs application-level network-performance measurements. However, the methodology is easily portable and can be interesting for basically any user application that performs large downloads or uploads and requires to estimate access network quality and its variation
Early diagnosis of cardiovascular diseases in workers: role of standard and advanced echocardiography
Cardiovascular disease (CVD) still remains the main cause of morbidity and mortality and consequently early diagnosis is of paramount importance. Working conditions can be regarded as an additional risk factor for CVD. Since different aspects of the job may affect vascular health differently, it is important to consider occupation from multiple perspectives to better assess occupational impacts on health. Standard echocardiography has several targets in the cardiac population, as the assessment of myocardial performance, valvular and/or congenital heart disease, and hemodynamics. Three-dimensional echocardiography gained attention recently as a viable clinical tool in assessing left ventricular (LV) and right ventricular (RV), volume, and shape. Two-dimensional (2DSTE) and, more recently, three-dimensional speckle tracking echocardiography (3DSTE) have also emerged as methods for detection of global and regional myocardial dysfunction in various cardiovascular diseases, and applied to the diagnosis of subtle LV and RV dysfunction. Although these novel echocardiographic imaging modalities have advanced our understanding of LV and RV mechanics, overlapping patterns often show challenges that limit their clinical utility. This review will describe the current state of standard and advanced echocardiography in early detection (secondary prevention) of CVD and address future directions for this potentially important diagnostic strategy
Electroweak bremsstrahlung for wino-like Dark Matter annihilations
If the Dark Matter is the neutral Majorana component of a multiplet which is
charged under the electroweak interactions of the Standard Model, its main
annihilation channel is into W+W-, while the annihilation into light fermions
is helicity suppressed. As pointed out recently, the radiation of gauge bosons
from the initial state of the annihilation lifts the suppression and opens up
an s-wave contribution to the cross section. We perform the full tree-level
calculation of Dark Matter annihilations, including electroweak bremsstrahlung,
in the context of an explicit model corresponding to the supersymmetric wino.
We find that the fermion channel can become as important as the di-boson one.
This result has significant implications for the predictions of the fluxes of
particles originating from Dark Matter annihilations.Comment: 13 pages, 3 figures. Minor corrections to match published versio
Dimension reduction via Gamma convergence for soft active materials
We present a rigorous derivation of dimensionally reduced theories for thin sheets of nematic elastomers, in the finite bending regime. Focusing on the case of twist nematic texture, we obtain 2D and 1D models for wide and narrow ribbons exhibiting spontaneous flexure and torsion. We also discuss some variants to the case of twist nematic texture, which lead to 2D models with different target curvature tensors. In particular, we analyse cases where the nematic texture leads to zero or positive Gaussian target curvature, and the case of bilayers. \ua9 2017 Springer Science+Business Media Dordrech
Coupled swelling and nematic reordering in liquid crystal gels
We derive a multiphysics model that accounts for network elasticity with
spontaneous strains, swelling and nematic interactions in liquid crystal gels
(LCGs). We discuss the coupling among the various physical mechanisms, with
particular reference to the effects of nematic interactions on chemical
equilibrium and that of swelling on the nematic-isotropic transition. Building
upon this discussion and using numerical simulations, we explore the transient
phenomena involving concurrent swelling and phase transition in LCGs subject to
a temperature change. Specifically, we demonstrate separation in time scales
between solvent uptake and phase change, in agreement with experiments, which
determines a kinetic decoupling between shape and volume changes. Finally, we
discuss possible applications in the context of microswimmers, where such a
kinetic decoupling is exploited to achieve non-reciprocal actuation and net
motion in Stokes flow
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