Jiří Hošek scite author profile

The analysis of color-superconducting two-flavor deconfined quark matter at moderate densities is extended to include a particular spin-1 Cooper pairing of those quarks which do not participate in the standard spin-0 diquark condensate. (i) The relativistic spin-1 gap ∆ ′ implies spontaneous breakdown of rotation invariance manifested in the form of the quasi-fermion dispersion law.(ii) The critical temperature of the anisotropic component is approximately given by the relationFor massless fermions the gas of anisotropic Bogolyubov-Valatin quasiquarks becomes effectively gapless and two-dimensional. Consequently, its specific heat depends quadratically on temperature. (iv) All collective Nambu-Goldstone excitations of the anisotropic phase have a linear dispersion law and the whole system remains a superfluid. (v) The system exhibits an electromagnetic Meissner effect.PACS numbers: 12.39. Ki, 12.38.Aw,11.30.Qc Recent investigations suggest that the phase structure of QCD is very rich [1,2]. At low temperatures and high densities strongly interacting matter is expected to be a color superconductor [3]. At asymptotically high densities, where the QCD coupling constant becomes small, this can be analyzed starting from first principles [4,5], whereas at more moderate densities, present (presumably) in the interiors of neutron stars, these methods are no longer justified. In this region the low-energy dynamics of deconfined quark matter is often studied employing effective Lagrangians L eff which contain local or non-local four-fermion interactions, most importantly interactions derived from instantons or on a more phenomenological basis [6,7,8]. The non-confining gluon SU (3) c gauge fields are then treated as weak external perturbations, and neglected in lowest approximation.In this letter we consider the case of two flavors which is most likely relevant at chemical potentials just above the deconfinement phase transition. On physical grounds it is then natural to assume that L eff favors the spontaneous formation of spin-0 isospin singlet Cooper pair condensates [1, 9] δ = ψ T C γ 5 τ 2 λ 2 ψ , where ψ is a quark field, C the matrix of charge conjugation, τ 2 a Pauli matrix which acts in flavor space, and λ 2 a GellMann matrix which acts in color space. Due to the latter SU (3) c is broken down to SU (2) c . This has the following consequences for the physical excitations of the system: (i) Corresponding to the mixing of the colors 1 and 2 there are two Bogolyubov-Valatin quasiquarks for each flavor with the dispersion law EThe energy gap ∆ is the solution of a selfconsistent gap equation and is found to be typically of the order ∼ 100 MeV in model calculations [6,7,8]. ǫ p = p 2 + M 2 , where M is an effective Dirac mass, related to the chiral condensate ψ ψ via a selfconsistency equation [8]. For each flavor there is an unpaired quark of color 3 with the dispersion law ǫ(ii) Because of the spontaneous breaking of SU (3) c down to SU (2) c five of the eight gluons receive a mass (Meissner effect), whereas thre...

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On perspective of security and privacy-preserving solutions in the internet of things

Malina

et al. 2016

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A Harmonized Perspective on Transportation Management in Smart Cities: The Novel IoT-Driven Environment for Road Traffic Modeling

Mašek

Masek

Frantík

et al. 2016

Sensors

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The unprecedented growth of today’s cities together with increased population mobility are fueling the avalanche in the numbers of vehicles on the roads. This development led to the new challenges for the traffic management, including the mitigation of road congestion, accidents, and air pollution. Over the last decade, researchers have been focusing their efforts on leveraging the recent advances in sensing, communications, and dynamic adaptive technologies to prepare the deployed road traffic management systems (TMS) for resolving these important challenges in future smart cities. However, the existing solutions may still be insufficient to construct a reliable and secure TMS that is capable of handling the anticipated influx of the population and vehicles in urban areas. Along these lines, this work systematically outlines a perspective on a novel modular environment for traffic modeling, which allows to recreate the examined road networks in their full resemblance. Our developed solution is targeted to incorporate the progress in the Internet of Things (IoT) technologies, where low-power, embedded devices integrate as part of a next-generation TMS. To mimic the real traffic conditions, we recreated and evaluated a practical traffic scenario built after a complex road intersection within a large European city.

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Jiří Hošek

On the oscillations of neutrinos with Dirac and Majorana masses

A Survey on Wearable Technology: History, State-of-the-Art and Current Challenges

Anisotropic Admixture in Color-Superconducting Quark Matter

On perspective of security and privacy-preserving solutions in the internet of things

A Harmonized Perspective on Transportation Management in Smart Cities: The Novel IoT-Driven Environment for Road Traffic Modeling

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