Year 2015

• The nonlinear effects of sound in a liquid with relaxation losses

  Publication

  • A. Perelomova

  - CANADIAN JOURNAL OF PHYSICS - Year 2015

  The nonlinear effects of sound in electrolyte with a chemical reaction are examined. The dynamic equations that govern non-wave modes in the field of intense sound are derived, and acoustic forces of vortex, entropy, and relaxation modes are determined in the cases of low-frequency sound and high-frequency sound. The difference in the nonlinear effects of sound in electrolyte and in a gas with excited vibrational degrees of molecules,...

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Year 2014

• Hysteresis curves for some periodic and aperiodic perturbations in gases

  Publication

  • A. Perelomova

  - CANADIAN JOURNAL OF PHYSICS - Year 2014

  Evolution of sound in a medium whose properties irreversibly vary in the course of wave propagation, is studied. For example, a gas that is a particular case of a Newtonian fluid is considered. Hysteresis curves, pictorial representations of irreversible attenuation of the sound energy, in the plane of thermodynamic states are plotted. The irreversible losses in internal energy are proportional to the total attenuation and depend...

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• Self-refraction of acoustic pulses with shock fronts in some nonequilibrium media

  Publication

  • A. Perelomova

  - CANADIAN JOURNAL OF PHYSICS - Year 2014

  The nonlinear self-refraction of acoustic pulsed beams, which include shock fronts, is studied. The medium of sound propagation is a gas where thermodynamically nonequilibrium processes take place, such as exothermic chemical reaction or excitation of vibrational degrees of a molecule’s freedom. Comparative analysis of the features of sound propagation over gases where pure nonlinear attenuation of the shock wave occurs, and gases...

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Year 2012

• Acoustic heating produced in resonators filled by a newtonian fluid

  Publication

  • A. Perelomova

  - CANADIAN JOURNAL OF PHYSICS - Year 2012

  Acoustic heating in resonators is studied. The governing equation of acoustic heating is derived by means of the special linear combination of conservation equations in differential form, allowing the reduction of all acoustic terms in the linear part of the final equation, but preserving terms belonging to the thermal mode responsible for heating. This equation is instantaneous and includes nonlinear acoustic terms that form a...

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Year 2011

• Propagation of acoustic pulses in some fluids with yield stress

  Publication

  • A. Perelomova

  - CANADIAN JOURNAL OF PHYSICS - Year 2011

  This study is devoted to the derivation of approximate equations governing acoustic pulses in flows with yieldstress, including some time-dependent flows with a slow dependence on time of yield stress and apparent viscosity. Themodeling of yield stress and apparent viscosity in the vicinity of a zero deformation rate allows us to consider a thixotropicfluid as a Bingham plastic with coefficients that are dependent on time. The...

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Year 2010

• Control of mass concentration of reagents by sound in a gas with nonequilibrium chemical reactions

  Publication

  • A. Perelomova

  - CANADIAN JOURNAL OF PHYSICS - Year 2010

  The weakly nonlinear dynamics of a chemically reacting gas is studied. Nonlinear interaction of acoustic and nonacoustic types of motion are considered. We decompose the base equations using the relationships of the gas-dynamic perturbations specific for every type of motion. The governing equation for the mass fraction of a reagent influenced by dominating sound is derived and discussed. The conclusions concern the equilibrium...

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• Nonlinear generation of non-acoustic modes by low-frequency sound in a vibrationally relaxing gas

  Publication

  • A. Perelomova

  - CANADIAN JOURNAL OF PHYSICS - Year 2010

  Two dynamic equations referring to a weakly nonlinear and weakly dispersive flow of a gas in which molecular vibrational relaxation takes place. are derived. The first one governs an excess temperature associated with the thermal mode, and the second one describes variations in vibrational energy. Both quantities refer to non-wave types of gas motion. These variations are caused by the nonlinear transfer of acoustic energy into...

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