Your search keyword '"wave and hydrodynamic model"' showing total 4 results

1. The collective behaviour of ensembles of condensing liquid drops on heterogeneous inclined substrates.

Author

Sebastian Engelnkemper and Uwe Thiele

Abstract

Employing a long-wave mesoscopic hydrodynamic model for the film height evolution we study ensembles of pinned and sliding drops of a volatile liquid that continuously condense onto a chemically heterogeneous inclined substrate. Our analysis combines, on the one hand, path continuation techniques to determine bifurcation diagrams for the depinning of single drops of nonvolatile liquid on single hydrophilic spots on a partially wettable substrate and, on the other hand, time simulations of growth and depinning of individual condensing drops as well as of the long-time behaviour of large ensembles of such drops. Pinned drops grow on the hydrophilic spots, depin and slide along the substrate while merging with other pinned drops and smaller drops that slide more slowly, and possibly undergo a pearling instability. As a result, the collective behaviour converges to a stationary state where condensation and outflow balance. The main features of the emerging drop size distribution can then be related to single-drop bifurcation diagrams. [ABSTRACT FROM AUTHOR]

Published

2019

2. Modeling relativistic heavy ion collisions

Author

A. K. Chaudhuri

Subjects

Quantum chromodynamics, Physics, Particle physics, Field (physics), High Energy Physics::Lattice, High Energy Physics::Phenomenology, Hadron, Quark–gluon plasma, Strong interaction, State of matter, Perfect fluid, Nuclear Experiment, Model building

Abstract

Relativistic heavy ion collision is a fascinating field of research. In recent years, the field has seen an unprecedented level of progress. A new state of matter, deconfined quark–gluon plasma (QGP), was predicted. An accelerator was built to detect this new state of matter. Experiments were performed and the discovery of the 'most perfect fluid' was made. Conclusive identification of the most perfect fluid state with the deconfined state has yet to be achieved. One of the impediments towards such identification is the fundamental property of the strong interaction, the 'color confinement', i.e. the constituents of the theory, the 'colored' quarks and gluons, are confined within a hadron. Any information about the deconfined state must be amassed from the color-neutral hadrons. And yet the process by which colored building blocks convert into a color singlet state is not properly understood. This necessitates model building. To young researchers, the field poses a problem in that it is multi-disciplinary, requiring knowledge of thermodynamics, statistical physics, kinetic theory, group theory, quantum chromodynamics (QCD), etc. The complexity of heavy ion collisions has necessarily led to a proliferation of models, e.g. the thermal model, blast wave model hydrodynamic model and models based on transport equations, etc, the physics of which need to be understood.

Published

2014

3. Signals of quark–gluon plasma

Author

A Chaudhuri

Subjects

Physics, Quantum chromodynamics, Particle physics, Field (physics), High Energy Physics::Lattice, High Energy Physics::Phenomenology, Strong interaction, Quark–gluon plasma, Hadron, State of matter, Strangeness production, Perfect fluid, Nuclear Experiment

Abstract

Relativistic heavy ion collision is a fascinating field of research. In recent years, the field has seen an unprecedented level of progress. A new state of matter, deconfined quark–gluon plasma (QGP), was predicted. An accelerator was built to detect this new state of matter. Experiments were performed and the discovery of the 'most perfect fluid' was made. Conclusive identification of the most perfect fluid state with the deconfined state has yet to be achieved. One of the impediments towards such identification is the fundamental property of the strong interaction, the 'color confinement', i.e. the constituents of the theory, the 'colored' quarks and gluons, are confined within a hadron. Any information about the deconfined state must be amassed from the color-neutral hadrons. And yet the process by which colored building blocks convert into a color singlet state is not properly understood. This necessitates model building. To young researchers, the field poses a problem in that it is multi-disciplinary, requiring knowledge of thermodynamics, statistical physics, kinetic theory, group theory, quantum chromodynamics (QCD), etc. The complexity of heavy ion collisions has necessarily led to a proliferation of models, e.g. the thermal model, blast wave model hydrodynamic model and models based on transport equations, etc, the physics of which need to be understood.

Published

2014

4. INJECTION AND ACCELERATION OF ELECTRONS AT A STRONG SHOCK: RADIO AND X-RAY STUDY OF YOUNG SUPERNOVA 2011dh.

Author

Maeda, Keiichi

Subjects

X-ray emission spectroscopy, SUPERNOVAE, ELECTRON research, SHOCK waves, COMPTON electrons

Abstract

In this paper, we develop a model for the radio and X-ray emissions from the Type IIb supernova (SN IIb) 2011dh in the first 100 days after the explosion, and investigate a spectrum of relativistic electrons accelerated at a strong shock wave. The widely accepted theory of particle acceleration, the so-called diffusive shock acceleration (DSA) or Fermi mechanism, requires seed electrons with modest energy with γ ∼ 1-100, and little is known about this pre-acceleration mechanism. We derive the energy distribution of relativistic electrons in this pre-accelerated energy regime. We find that the efficiency of the electron acceleration must be low, i.e., εe ≲ 10–2 as compared to the conventionally assumed value of εe ∼ 0.1. Furthermore, independent of the low value of εe, we find that the X-ray luminosity cannot be attributed to any emission mechanisms suggested as long as these electrons follow the conventionally assumed single power-law distribution. A consistent view between the radio and X-ray can only be obtained if the pre-acceleration injection spectrum peaks at γ ∼ 20-30 and then only a fraction of these electrons eventually experience the DSA-like acceleration toward the higher energy—then the radio and X-ray properties are explained through the synchrotron and inverse Compton mechanisms, respectively. Our findings support the idea that the pre-acceleration of the electrons is coupled with the generation/amplification of the magnetic field. [ABSTRACT FROM AUTHOR]

Published

2012