3,388 research outputs found
Heat Current Characteristics in Nanojunctions with Superconducting Leads
As a fundamental requisite for thermotronics, controlling heat flow has been
a longstanding quest in solid state physics. Recently, there has been a lot of
interest in nanoscale hybrid systems as possible candidates for thermal
devices. In this context, we study the heat current in the simplest hybrid
device of a two level system weakly coupled to two heat baths. We use the
reduced density matrix approach together with a simple Born-Markov
approximation to calculate the heat current in the steady state. We consider
different kinds of reservoirs and show that the nature of the reservoir plays a
very important role in determining the thermal characteristics of the device.
In particular, we investigate the effectiveness of a conventional
superconductor as a reservoir with regard to manipulating the heat current. In
the emergent temperature characteristics, we find that superconductivity in the
reservoirs leads to enhanced thermal currents and that the superconducting
phase transition is clearly visible in the heat current. We observe negative
differential thermal conductance and a pronounced rectification of the heat
current, making this a good building block for a quantum thermal diode.Comment: 10 pages, 6 figures, submitted to Physical Review
Collider signals of gravitino dark matter in bilinearly broken R-parity
In models with gauge mediated supersymmetry breaking the gravitino is the
lightest supersymmetric particle. If R-parity is violated the gravitino decays,
but with a half-live far exceeding the age of the universe and thus is, in
principle, a candidate for the dark matter. We consider the decays of the
next-to-lightest supersymmetric particle, assumed to be the neutralino. We show
that in models where the breaking of R-parity is bilinear, the condition that
R-parity violation explains correctly the measured neutrino masses fixes the
branching ratio of the decay in the
range , if the gravitino mass is in the range required to
solve the dark matter problem, i.e. of the order (few) 100 eV. This scenario is
therefore directly testable at the next generation of colliders.Comment: 13 pages, 3 figure
Negative-energy perturbations in cylindrical equilibria with a radial electric field
The impact of an equilibrium radial electric field on negative-energy
perturbations (NEPs) (which are potentially dangerous because they can lead to
either linear or nonlinear explosive instabilities) in cylindrical equilibria
of magnetically confined plasmas is investigated within the framework of
Maxwell-drift kinetic theory. It turns out that for wave vectors with a
non-vanishing component parallel to the magnetic field the conditions for the
existence of NEPs in equilibria with E=0 [G. N. Throumoulopoulos and D.
Pfirsch, Phys. Rev. E 53, 2767 (1996)] remain valid, while the condition for
the existence of perpendicular NEPs, which are found to be the most important
perturbations, is modified. For ( is the
electrostatic potential) and ( is
the total plasma pressure), a case which is of operational interest in magnetic
confinement systems, the existence of perpendicular NEPs depends on ,
where is the charge of the particle species . In this case the
electric field can reduce the NEPs activity in the edge region of tokamaklike
and stellaratorlike equilibria with identical parabolic pressure profiles, the
reduction of electron NEPs being more pronounced than that of ion NEPs.Comment: 30 pages, late
Negative-Energy Perturbations in Circularly Cylindrical Equilibria within the Framework of Maxwell-Drift Kinetic Theory
The conditions for the existence of negative-energy perturbations (which
could be nonlinearly unstable and cause anomalous transport) are investigated
in the framework of linearized collisionless Maxwell-drift kinetic theory for
the case of equilibria of magnetically confined, circularly cylindrical plasmas
and vanishing initial field perturbations. For wave vectors with a
non-vanishing component parallel to the magnetic field, the plane equilibrium
conditions (derived by Throumoulopoulos and Pfirsch [Phys Rev. E {\bf 49}, 3290
(1994)]) are shown to remain valid, while the condition for perpendicular
perturbations (which are found to be the most important modes) is modified.
Consequently, besides the tokamak equilibrium regime in which the existence of
negative-energy perturbations is related to the threshold value of 2/3 of the
quantity , a new
regime appears, not present in plane equilibria, in which negative-energy
perturbations exist for {\em any} value of . For various analytic
cold-ion tokamak equilibria a substantial fraction of thermal electrons are
associated with negative-energy perturbations (active particles). In
particular, for linearly stable equilibria of a paramagnetic plasma with flat
electron temperature profile (), the entire velocity space is
occupied by active electrons. The part of the velocity space occupied by active
particles increases from the center to the plasma edge and is larger in a
paramagnetic plasma than in a diamagnetic plasma with the same pressure
profile. It is also shown that, unlike in plane equilibria, negative-energy
perturbations exist in force-free reversed-field pinch equilibria with a
substantial fraction of active particles.Comment: 31 pages, late
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Novel Higgs decay signals in R-parity violating models
In supersymmetric models the lightest Higgs boson may decay with a sizable
branching ratio into a pair of light neutralinos. We analyze such decays within
the context of the minimal supersymmetric standard model with R-parity
violation, where the neutralino itself is unstable and decays into Standard
Model fermions. We show that the R-parity violating couplings induce novel
Higgs decay signals that might facilitate the discovery of the Higgs boson at
colliders. At the LHC, the Higgs may be observed, for instance, through its
decay -via two neutralinos- into final states containing missing energy and
isolated charged leptons such as , and .
Another promising possibility is the search for the displaced vertices
associated with the neutralino decay. We also point out that Higgs searches at
the LHC might additionally provide the first evidence of R-parity violation.Comment: 15 pages, 7 figures. Corrected affiliation
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