Application of electrically controlled interference for observing the autowave process in the near-electrode layer of a magnetic fluid and in an electrically tunable color filter

“…The main idea of constructing such a model is to study the question of the possibility of the occurrence of autowave motion due to the recharging of MF particles near the electrodes or in the regions of localization of the space charge. The model is described by a boundary-value problem, which consists of a research area (Figure 6), a system of equations (6)(7)(8)(9)(10)(11)(12), and initial and boundary conditions (13)(14)(15)(16)(17)(18)(19)(20). When constructing the model, the following assumptions were made:…”

“…Under these assumptions, we made a model, which is described by the systems of coupled partial differential equations of Nernst-Planck-Poisson and Navier-Stokes, based on the basic physical laws of the conservation of matter and energy (6)(7)(8)(9)(10)(11)(12) and boundary conditions (13)(14)(15)(16)(17)(18)(19)(20)(21)(22)(23):…”

“…The Nernst-Planck Equation ( 6) describes the flow of charged particles of the dispersed phase of a magnetic fluid due to migration in an electric field, diffusion and convection, the charge numbers of positively charged particles The process of the wave appearance is associated with the process of the charging and recharging of particles, which is reflected in the boundary conditions (13)(14)(15)(16)(17)(18)(19)(20)(21)(22)(23).…”

“…As noted above, the recharging of magnetic fluid particles occurs in a liquid membrane located at the cathode and with a small thickness, due to ions injected from the cathode, which cannot "slip" through the liquid membrane and recombine with heteroions. This allows one to abstract from the thickness of the membrane and its location and represent it by the plane x = H. Moreover, let us assume that this plane is equipotential and negatively charged, i.e., is simultaneously a cathode (18).…”

“…The presence of magnetic particles in the near-electrode regions has a significant influence on the electrophysical and optical effects, which are specific for magnetic fluids and are not observed in other liquid dielectrics. For example, when a cell with magnetic fluid is illuminated with light with a wide spectrum of wavelengths in an electric field, we see a change in the color of the electrode surface, which is explained by a shift in the spectrum maximum due to the formation of a near-electrode layer of particles and an increase in the optical thickness of the layer [18]. Labyrinth structures of ordered microdroplet aggregates are formed in a thin layer of a magnetic colloid [19].…”

Experimental and Theoretical Study of an Autowave Process in a Magnetic Fluid

“…The main idea of constructing such a model is to study the question of the possibility of the occurrence of autowave motion due to the recharging of MF particles near the electrodes or in the regions of localization of the space charge. The model is described by a boundary-value problem, which consists of a research area (Figure 6), a system of equations (6)(7)(8)(9)(10)(11)(12), and initial and boundary conditions (13)(14)(15)(16)(17)(18)(19)(20). When constructing the model, the following assumptions were made:…”

“…Under these assumptions, we made a model, which is described by the systems of coupled partial differential equations of Nernst-Planck-Poisson and Navier-Stokes, based on the basic physical laws of the conservation of matter and energy (6)(7)(8)(9)(10)(11)(12) and boundary conditions (13)(14)(15)(16)(17)(18)(19)(20)(21)(22)(23):…”

“…The Nernst-Planck Equation ( 6) describes the flow of charged particles of the dispersed phase of a magnetic fluid due to migration in an electric field, diffusion and convection, the charge numbers of positively charged particles The process of the wave appearance is associated with the process of the charging and recharging of particles, which is reflected in the boundary conditions (13)(14)(15)(16)(17)(18)(19)(20)(21)(22)(23).…”

“…As noted above, the recharging of magnetic fluid particles occurs in a liquid membrane located at the cathode and with a small thickness, due to ions injected from the cathode, which cannot "slip" through the liquid membrane and recombine with heteroions. This allows one to abstract from the thickness of the membrane and its location and represent it by the plane x = H. Moreover, let us assume that this plane is equipotential and negatively charged, i.e., is simultaneously a cathode (18).…”

“…The presence of magnetic particles in the near-electrode regions has a significant influence on the electrophysical and optical effects, which are specific for magnetic fluids and are not observed in other liquid dielectrics. For example, when a cell with magnetic fluid is illuminated with light with a wide spectrum of wavelengths in an electric field, we see a change in the color of the electrode surface, which is explained by a shift in the spectrum maximum due to the formation of a near-electrode layer of particles and an increase in the optical thickness of the layer [18]. Labyrinth structures of ordered microdroplet aggregates are formed in a thin layer of a magnetic colloid [19].…”

Experimental and Theoretical Study of an Autowave Process in a Magnetic Fluid

Experimental and Theoretical Study of Forced Synchronization of Self-Oscillations in Liquid Ferrocolloid Membranes