Theoretical Modeling of Average Force Acted on Nano Plasma Spheres in Presence of Radiation of Long Wavelength Point Source

Hajijamali-Arani, Zeinab; Jazi, B.; Jahanbakht, Sajad

doi:10.1007/s11468-016-0382-3

Cited by 6 publications

(3 citation statements)

References 43 publications

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“…It is evident that the basic electromagnetic laws such as the charge conservation are confirmed by considering all the terms in the expansion. In our previous work [57] without speaking about thermal effects, we focused on a theoretical modeling of the average force acted on the cold nano plasma spheres (NPSs) in the presence of the radiation of the long wavelength point source (in the quasi-static approximation). In [57], the oscillations with the phase velocity much higher than thermal velocities of the NPSs were studied and the surface charge densities, which, referring to plasmon, in the form of the force were effective.…”

Section: Introductionmentioning

confidence: 99%

“…In our previous work [57] without speaking about thermal effects, we focused on a theoretical modeling of the average force acted on the cold nano plasma spheres (NPSs) in the presence of the radiation of the long wavelength point source (in the quasi-static approximation). In [57], the oscillations with the phase velocity much higher than thermal velocities of the NPSs were studied and the surface charge densities, which, referring to plasmon, in the form of the force were effective. As discussed in [57], the presence of the point source near the NPS gives rise to a series of resonances at a unique regime.…”

Section: Introductionmentioning

confidence: 99%

“…In [57], the oscillations with the phase velocity much higher than thermal velocities of the NPSs were studied and the surface charge densities, which, referring to plasmon, in the form of the force were effective. As discussed in [57], the presence of the point source near the NPS gives rise to a series of resonances at a unique regime. In the present work, the attention mostly will be paid to a classical description of the optical response of the hot nano plasma spheres (HNPSs) in a colloidal solution (including ion radiators with two different profiles).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

A theoretical study for temperature effects on the dominant color in colloidal nano sphere solutions

Hajijamali-Arani¹,

Jazi²

2019

Phys. Scr.

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The effects of the electron temperature on the dominant color in colloidal nano sphere solutions are analytically studied. This system contains ions (as radiators) close to the hot nano plasma spheres (HNPSs). Considering two separate models of the point radiated ions and applying the fluid dynamic equations and suitable Green’s function, the optical resonance of HNPSs is declared. The thermal effects in HNPSs show that a series of optical resonances occur in the system and the dominant resonance frequencies depend on the plasma geometry, electron density, electron temperature. The resonance frequencies in the two different models are exactly identical. Also, a new type of resonance frequency (subsidiary resonance frequencies), resulting in the thermal effects, is seen by considering two radiators beside the HNPS and, in this case, due to the sign of the ion radiators with same strengths, the even or odd modes are excited, separately. In other words, the permissible resonance frequencies in colloidal nano sphere solutions are categorized into two principal types: dominant resonance frequencies and subsidiary resonance frequencies. In addition, the graphs of the scattering patterns and resonance frequencies of this problem are analyzed. All of the resonance frequencies are varied with the temperature so that decreasing the Debye length (temperature) of HNPSs decreases the resonant frequencies and changes the dominant color of the system. Moreover, the dominant color of the system depends on the number of spheres in a colloidal solution including many bodies of nano-spheres with different radii.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

A theoretical study for temperature effects on the dominant color in colloidal nano sphere solutions

Hajijamali-Arani¹,

Jazi²

2019

Phys. Scr.

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Analytical formulation for the dielectric tensor and field equations of the inhomogeneous drift plasma cylinder in rotating magnetic field

Hajijamali-Arani

Jazi

2017

Physics of Plasmas

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In this procedure, the fundamental electromagnetic equations and fluid equations in a cylindrical coordinate system for a new drift plasma configuration have been analyzed. The system is a long nonhomogeneous drift plasma column, which is imbedded in a uniform transverse magnetic field rotating about the symmetric axis of the system. The elements of the dielectric permittivity tensor are obtained for a pattern propagating in an arbitrary direction, and coupling equations of fields will be derived. It will be observed that the time variable dielectric tensor can be written as non-operational Hermitian and pure spatial operational parts which satisfy the limiting special cases.

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The classical and theoretical simulation for dominant radiated frequencies of plasma nanowire in presence of a long monopole antenna with long wavelength radiation

Safari

Jazi

2017

Journal of Applied Physics

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A theoretical model based on the classical theory for the simulation of scattering phenomena of long wavelength electromagnetic waves from plasma nanowires is investigated. A line source as a monopole antenna radiator is considered, which radiates with frequency ω in the vicinity of plasma nanowires parallel to the nanowire axis. A mathematical relation for resonance frequency is obtained. It is shown that in the resonance situation, plasma nanowires represent most of the response to the presence of electromagnetic waves. Mathematical computations are done for both the cold and warm approximations of plasma cases. The diagrams of the variation of resonance frequency versus the variation of temperature, geometrical dimension, and carrier density of plasma nanowires are presented. Also, a mathematical relation for subsidiary resonance frequency with considering two line sources with opposite charge is offered. The diagrams of subsidiary resonance frequency versus the variation of temperature, geometrical dimension, and carrier density of plasma nanowires are presented. It is shown that the presented model provides a color diagnostic system for the determination of size, the number, and distribution of nanowires immersed in a fluid based on their temperature and geometrical dimension.

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Theoretical Modeling of Average Force Acted on Nano Plasma Spheres in Presence of Radiation of Long Wavelength Point Source

Cited by 6 publications

References 43 publications

A theoretical study for temperature effects on the dominant color in colloidal nano sphere solutions

A theoretical study for temperature effects on the dominant color in colloidal nano sphere solutions

Analytical formulation for the dielectric tensor and field equations of the inhomogeneous drift plasma cylinder in rotating magnetic field

The classical and theoretical simulation for dominant radiated frequencies of plasma nanowire in presence of a long monopole antenna with long wavelength radiation

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