Your search keyword '"Ali, A. A."' showing total 16 results

1. Linear and nonlinear dynamics of current-driven waves in dusty plasmas.

Author

Ahmad, Ali, Ali Shan, S., Haque, Q., and Saleem, H.

Subjects

*DUSTY plasmas, *NONLINEAR theories, *MAGNETIC fields, *THERMAL electrons, *VORTEX motion, *MAGNETOSPHERE, *ION acoustic waves

Abstract

The linear and nonlinear dynamics of a recently proposed plasma mode of dusty plasma is studied using kappa distribution for electrons. This electrostatic wave can propagate in the plasma due to the sheared flow of electrons and ions parallel to the external magnetic field in the presence of stationary dust. The coupling of this wave with the usual drift wave and ion acoustic wave is investigated. D'Angelo's mode is also modified in the presence of superthermal electrons. In the nonlinear regime, the wave can give rise to dipolar vortex structures if the shear in flow is weaker and tripolar vortices if the flow has steeper gradient. The results have been applied to Saturn's magnetosphere corresponding to negatively charged dust grains. But the theoretical model is applicable for positively charged dust as well. This work will be useful for future observations and studies of dusty environments of planets and comets. [ABSTRACT FROM AUTHOR]

Published

2012

2. Dust-lower-hybrid instability with fluctuating charge in quantum plasmas.

Author

Jamil, M., Ali, M., Rasheed, A., Zubia, K., and Salimullah, M.

Subjects

*PLASMA instabilities, *QUANTUM plasmas, *PLASMA gases, *DUST, *HYDRODYNAMICS, *MAGNETIC fields

Abstract

The instability of Dust-Lower-Hybrid (DLH) wave is examined in detail in the uniform dusty magnetoplasmas. The time dependent charging effects on dust particles around its equilibrium charge Qd0 are taken into account based on Orbit-Limited Probe theory. The quantum characteristics of the system like Bohm potential and Fermi degenerate pressure are dealt using the quantum hydrodynamic model of plasmas. The external magnetic field and size of the dust particles have new physical effects over the dissipative instability of DLH wave in the quantum plasma regime. [ABSTRACT FROM AUTHOR]

Published

2015

3. An accurate symplectic calculation of the inboard magnetic footprint from statistical topological noise and field errors in the DIII-D.

Author

Punjabi, Alkesh and Ali, Halima

Subjects

*SYMPLECTIC geometry, *TOPOLOGY, *ERROR analysis in mathematics, *MAGNETIC fields, *NOISE control, *HAMILTONIAN systems, *FUSION reactors

Abstract

Any canonical transformation of Hamiltonian equations is symplectic, and any area-preserving transformation in 2D is a symplectomorphism. Based on these, a discrete symplectic map and its continuous symplectic analog are derived for forward magnetic field line trajectories in natural canonical coordinates. The unperturbed axisymmetric Hamiltonian for magnetic field lines is constructed from the experimental data in the DIII-D [J. L. Luxon and L. E. Davis, Fusion Technol. 8, 441 (1985)]. The equilibrium Hamiltonian is a highly accurate, analytic, and realistic representation of the magnetic geometry of the DIII-D. These symplectic mathematical maps are used to calculate the magnetic footprint on the inboard collector plate in the DIII-D. Internal statistical topological noise and field errors are irreducible and ubiquitous in magnetic confinement schemes for fusion. It is important to know the stochasticity and magnetic footprint from noise and error fields. The estimates of the spectrum and mode amplitudes of the spatial topological noise and magnetic errors in the DIII-D are used as magnetic perturbation. The discrete and continuous symplectic maps are used to calculate the magnetic footprint on the inboard collector plate of the DIII-D by inverting the natural coordinates to physical coordinates. The combination of highly accurate equilibrium generating function, natural canonical coordinates, symplecticity, and small step-size together gives a very accurate calculation of magnetic footprint. Radial variation of magnetic perturbation and the response of plasma to perturbation are not included. The inboard footprint from noise and errors are dominated by m=3, n=1 mode. The footprint is in the form of a toroidally winding helical strip. The width of stochastic layer scales as 12 power of amplitude. The area of footprint scales as first power of amplitude. The physical parameters such as toroidal angle, length, and poloidal angle covered before striking, and the safety factor all have fractal structure. The average field diffusion near the X-point for lines that strike and that do not strike differs by about three to four orders of magnitude. The magnetic footprint gives the maximal bounds on size and heat flux density on collector plate. [ABSTRACT FROM AUTHOR]

Published

2011

4. Propagation of the three-dimensional dust acoustic solitons in magnetized quantum plasmas with dust polarity effect.

Author

Sadiq, M., Ali, S., and Sabry, R.

Subjects

*SOLITONS, *DUSTY plasmas, *HYDRODYNAMICS, *QUANTUM theory, *MAGNETIC fields, *QUANTUM wells

Abstract

The quantum hydrodynamical model is employed to investigate the nonlinear properties of the quantum dust acoustic waves in a magnetized dusty plasma composed of inertialess electrons, ions, and mobile positive/negative charged dust particles. For this purpose, a quantum Zakharov–Kuznetsov equation is derived and the basic features of the electrostatic excitations are investigated by applying the direct method. It is found that positive and negative bell-shaped solitary pulses become explosive pulses depending mainly upon the angles of propagation and dust polarity. Furthermore, the effects due to nondimensional quantum parameter and the external magnetic field are examined on the width of the quantum dust acoustic solitary pulses. The relevance of the present results to semiconductor quantum wells is mentioned. [ABSTRACT FROM AUTHOR]

Published

2009

5. Symplectic approach to calculation of magnetic field line trajectories in physical space with realistic magnetic geometry in divertor tokamaks.

Author

Punjabi, Alkesh and Ali, Halima

Subjects

*MAGNETIC fields, *FIELD theory (Physics), *GENERATING functions, *MAGNETIC flux, *ELECTROMAGNETIC induction, *FUSION reactors

Abstract

A new approach to integration of magnetic field lines in divertor tokamaks is proposed. In this approach, an analytic equilibrium generating function (EGF) is constructed in natural canonical coordinates (ψ,θ) from experimental data from a Grad–Shafranov equilibrium solver for a tokamak. ψ is the toroidal magnetic flux and θ is the poloidal angle. Natural canonical coordinates (ψ,θ,φ) can be transformed to physical position (R,Z,φ) using a canonical transformation. (R,Z,φ) are cylindrical coordinates. Another canonical transformation is used to construct a symplectic map for integration of magnetic field lines. Trajectories of field lines calculated from this symplectic map in natural canonical coordinates can be transformed to trajectories in real physical space. Unlike in magnetic coordinates [O. Kerwin, A. Punjabi, and H. Ali, Phys. Plasmas 15, 072504 (2008)], the symplectic map in natural canonical coordinates can integrate trajectories across the separatrix surface, and at the same time, give trajectories in physical space. Unlike symplectic maps in physical coordinates (x,y) or (R,Z), the continuous analog of a symplectic map in natural canonical coordinates does not distort trajectories in toroidal planes intervening the discrete map. This approach is applied to the DIII-D tokamak [J. L. Luxon and L. E. Davis, Fusion Technol. 8, 441 (1985)]. The EGF for the DIII-D gives quite an accurate representation of equilibrium magnetic surfaces close to the separatrix surface. This new approach is applied to demonstrate the sensitivity of stochastic broadening using a set of perturbations that generically approximate the size of the field errors and statistical topological noise expected in a poloidally diverted tokamak. Plans for future application of this approach are discussed. [ABSTRACT FROM AUTHOR]

Published

2008

6. Modeling of stochastic broadening in a poloidally diverted discharge with piecewise analytic symplectic mapping flux functions.

Author

Punjabi, Alkesh, Ali, Halima, Evans, Todd, and Boozer, Allen

Subjects

*MAGNETIC fields, *HAMILTONIAN systems, *QUANTUM perturbations, *QUANTUM theory, *PLASMA dynamics, *MAGNETOHYDRODYNAMICS, *PHYSICS

Abstract

A highly accurate calculation of the magnetic field line Hamiltonian in DIII-D [J. L. Luxon and L. E. Davis, Fusion Technol. 8, 441 (1985)] is made from piecewise analytic equilibrium fit data for shot 115467 3000 ms. The safety factor calculated from this Hamiltonian has a logarithmic singularity at an ideal separatrix. The logarithmic region inside the ideal separatrix contains 2.5% of toroidal flux inside the separatrix. The logarithmic region is symmetric about the separatrix. An area-preserving map for the field line trajectories is obtained in magnetic coordinates from the Hamiltonian equations of motion for the lines and a canonical transformation. This map is used to calculate trajectories of magnetic field lines in DIII-D. The field line Hamiltonian in DIII-D is used as the generating function for the map and to calculate stochastic broadening from field-errors and spatial noise near the separatrix. A very negligible amount (0.03%) of magnetic flux is lost from inside the separatrix due to these nonaxisymmetric fields. It is quite easy to add magnetic perturbations to generating functions and calculate trajectories for maps in magnetic coordinates. However, it is not possible to integrate across the separatrix. It is also difficult to find the physical position corresponding to magnetic coordinates. For open field lines, periodicity in the poloidal angle is assumed, which is not satisfactory. The goal of this paper is to demonstrate the efficacy of the symplectic mapping approach rather than using realistic DIII-D parameters or modeling specific experimental results. [ABSTRACT FROM AUTHOR]

Published

2008

7. Effects of low and high mode number tearing modes in divertor tokamaks.

Author

Punjabi, Alkesh, Ali, Halima, Boozer, Allen, and Evans, Todd

Subjects

*TOKAMAKS, *QUANTUM perturbations, *MAGNETIC fields, *HAMILTONIAN systems, *MAGNETIC dipoles, *MAPS

Abstract

The topological effects of magnetic perturbations on a divertor tokamak, such as DIII-D, are studied using field-line maps that were developed by Punjabi et al. [A. Punjabi, A. Verma, and A. Boozer, Phys. Rev. Lett. 69, 3322 (1992)]. The studies consider both long-wavelength perturbations, such as those of m=1, n=1 tearing modes, and localized perturbations, which are represented as a magnetic dipole. The parameters of the dipole map are set using DIII-D data from shot 115467 in which the C-coils were activated [J. L. Luxon and L. E. Davis, Fusion Technol. 8, 441 (1985)]. The long-wavelength perturbations alter the structure of the interception of magnetic field lines with the divertor plates, but the interception is in sharp lines. The dipole perturbations cause a spreading of the interception of the field lines with the divertor plates, which alleviates problems associated with heat deposition. Magnetic field lines are the trajectories of a one-and-a-half degree of freedom Hamiltonian, which strongly constrains the topological features of the lines. Although the field line maps that we use do not accurately represent the trajectories through ordinary space of individual field lines, they do represent their topological structure. [ABSTRACT FROM AUTHOR]

Published

2007

8. Derivation of the dipole map.

Author

Ali, Halima, Punjabi, Alkesh, and Boozer, Allen

Subjects

*PLASMA gases, *IONIZED gases, *DYNAMICS, *ANALYTICAL mechanics, *MAGNETIC fields, *FIELD theory (Physics)

Abstract

In our method of maps [Punjabi et al., Phy. Rev. Lett. 69, 3322 (1992), and Punjabi et al., J. Plasma Phys. 52, 91 (1994)], symplectic maps are used to calculate the trajectories of magnetic field lines in divertor tokamaks. Effects of the magnetic perturbations are calculated using the low MN map [Ali et al., Phys. Plasmas 11, 1908 (2004)] and the dipole map [Punjabi et al., Phys. Plasmas 10, 3992 (2003)]. The dipole map is used to calculate the effects of externally located current carrying coils on the trajectories of the field lines, the stochastic layer, the magnetic footprint, and the heat load distribution on the collector plates in divertor tokamaks [Punjabi et al., Phys. Plasmas 10, 3992 (2003)]. Symplectic maps are general, efficient, and preserve and respect the Hamiltonian nature of the dynamics. In this brief communication, a rigorous mathematical derivation of the dipole map is given. [ABSTRACT FROM AUTHOR]

Published

2004

9. Effects of dipole perturbation on the stochastic layer and magnetic footprint in single-null divertor tokamaks.

Author

Punjabi, Alkesh, Ali, Halima, and Boozer, Allen

Subjects

*MAGNETIC fields, *TOKAMAKS, *PERTURBATION theory

Abstract

In this paper, the method of maps is used to calculate the effects of high toroidal and poloidal mode number perturbation on the trajectories of magnetic field lines in a single-null divertor tokamak. First, a simplified derivation of the dipole map from the Hamiltonian mechanics of magnetic field is given. This map represents the effects of an externally located current carrying coil on the motion of field lines. The unperturbed magnetic field topology of a single-null divertor tokamak is represented by the symmetric simple map. The coil is placed across from the X-point on the line joining the X-point and the O-point at a fixed distance from the last good confining surface. The effects of coil on the stochastic layer and magnetic footprint are calculated using the symmetric simple map and the dipole map. Self-similarities, singularities, and topological equivalences in the pattern of physical parameters are found that characterize the stochastic layer and the magnetic footprint. The dipole perturbation increases the area of footprint, drastically reduces the fraction of heat flux escaping the stochastic layer, disperses the heat flux more evenly over a wider area, and reduces number of hotspots on the collector plate. © 2003 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2003

10. Symmetric simple map for a single-null divertor tokamak.

Author

Punjabi, Alkesh, Ali, Halima, and Boozer, Allen

Subjects

*TOKAMAKS, *MAGNETIC fields

Abstract

Introduces the symmetric simple map for the representation of chaotic trajectories of magnetic field lines in the scrape-off layer of a single-null divertor tokamak. Representation of the magnetic topology of a single-null divertor tokamak; Investigation of the map in detail; Employment of the map in the calculation of the variations in the fraction of magnetic flux.

Published

1997

11. Short scale electrostatic vortices driven by electrons sheared flow parallel to external magnetic field in heavier ion plasmas.

Author

Ahmad, Ali and Saleem, H.

Subjects

*ELECTROSTATICS, *QUANTUM perturbations, *MAGNETIC fields, *ION acoustic waves, *NONLINEAR theories, *TRANSPORT theory, *ELECTRON beams, *PLASMA gases

Abstract

Nonlinear equations for an electrostatic perturbation in hybrid frequency range are derived in a magnetized heavier ion plasma assuming that the electrons are flowing with a sheared velocity along the initial external constant magnetic field B0zz⁁. As a result of this current, the total zero-order magnetic field becomes sheared as B0=B0zz⁁+B0y(x)y⁁. Such a system can give rise to unstable electrostatic waves under certain conditions. The solutions of the nonlinear equations are obtained in the form of dipolar vortices, which can play an important role in plasma transport across field lines. This work can be useful for the future experiments on sheared electron flows. [ABSTRACT FROM AUTHOR]

Published

2012

12. Nonlinear instability of an Oldroyd elastico-viscous magnetic nanofluid saturated in a porous medium.

Author

Moatimid, Galal M., Alali, Elham M. M., and Ali, Hoda S. M.

Subjects

*NONLINEAR systems, *VISCOUS flow, *NANOFLUIDS, *POROUS materials, *MAGNETIC fields, *VISCOELASTICITY

Abstract

Through viscoelastic potential theory, a Kelvin-Helmholtz instability of two semi-infinite fluid layers, of Oldroydian viscoelastic magnetic nanofluids (MNF), is investigated. The system is saturated by porous medium through two semi-infinite fluid layers. The Oldroyd B model is utilized to describe the rheological behavior of viscoelastic MNF. The system is influenced by uniform oblique magnetic field that acts at the surface of separation. The model is used for the MNF incorporated the effects of uniform basic streaming and viscoelasticity. Therefore, a mathematical simplification must be considered. A linear stability analysis, based upon the normal modes analysis, is utilized to find out the solutions of the equations of motion. The onset criterion of stability is derived; analytically and graphs have been plotted by giving numerical values to the various parameters. These graphs depict the stability characteristics. Regions of stability and instability are identified and discussed in some depth. Some previous studies are recovered upon appropriate data choices. The stability criterion in case of ignoring the relaxation stress times is also derived. To relax the mathematical manipulation of the nonlinear approach, the linearity of the equations of motion is taken into account in correspondence with the nonlinear boundary conditions. Taylor's theory is adopted to expand the governing nonlinear characteristic equation according to of the multiple time scales technique. This analysis leads to the well-known Ginzburg-Landau equation, which governs the stability criteria. The stability criteria are achieved theoretically. To simplify the mathematical manipulation, a special case is considered to achieve the numerical estimations. The influence of orientation of the magnetic fields on the stability configuration, in linear as well as nonlinear approaches, makes a dual role for the magnetic field strength in the stability graphs. Stability diagram is plotted for different sets of physical parameters. A new stability as well as instability region, in the parameter space, appears due to the nonlinear effects. [ABSTRACT FROM AUTHOR]

Published

2014

13. The symmetric quartic map for trajectories of magnetic field lines in elongated divertor tokamak plasmas.

Author

Jones, Morgin, Wadi, Hasina, Ali, Halima, and Punjabi, Alkesh

Subjects

*DIFFUSION, *SEMICONDUCTOR doping, *TOKAMAKS, *MAGNETIC fields, *MAGNETIC flux

Abstract

The coordinates of the area-preserving map equations for integration of magnetic field line trajectories in divertor tokamaks can be any coordinates for which a transformation to (ψt,θ,φ) coordinates exists [A. Punjabi, H. Ali, T. Evans, and A. Boozer, Phys. Lett. A 364, 140 (2007)]. ψt is toroidal magnetic flux, θ is poloidal angle, and φ is toroidal angle. This freedom is exploited to construct the symmetric quartic map such that the only parameter that determines magnetic geometry is the elongation of the separatrix surface. The poloidal flux inside the separatrix, the safety factor as a function of normalized minor radius, and the magnetic perturbation from the symplectic discretization are all held constant, and only the elongation is κ varied. The width of stochastic layer, the area, and the fractal dimension of the magnetic footprint and the average radial diffusion coefficient of magnetic field lines from the stochastic layer; and how these quantities scale with κ is calculated. The symmetric quartic map gives the correct scalings which are consistent with the scalings of coordinates with κ. The effects of m=1, n=±1 internal perturbation with the amplitude that is expected to occur in tokamaks are calculated by adding a term [H. Ali, A. Punjabi, A. H. Boozer, and T. Evans, Phys. Plasmas 11, 1908 (2004)] to the symmetric quartic map. In this case, the width of stochastic layer scales as 0.35 power of κ. The area of the footprint is roughly constant. The average radial diffusion coefficient of field lines near the X-point scales linearly with κ. The low mn perturbation changes the quasisymmetric structure of the footprint, and reorganizes it into a single, large scale, asymmetric structure. The symmetric quartic map is combined with the dipole map [A. Punjabi, H. Ali, and A. H. Boozer, Phys. Plasmas 10, 3992 (2003)] to calculate the effects of magnetic perturbation from a current carrying coil. The coil position and coil current coil are constant. The dipole perturbation enhances the magnetic shear. The width of the stochastic layer scales exponentially with κ. The area of the footprint decreases as the κ increases. The radial diffusion coefficient of field lines scales exponentially with κ. The dipole perturbation changes the topology of the footprint. It breaks up the toroidally spiraling footprint into a number of separate asymmetric toroidal strips. Practical applications of the symmetric quartic map to elongated divertor tokamak plasmas are suggested. [ABSTRACT FROM AUTHOR]

Published

2009

14. Simple map in action-angle coordinates.

Author

Kerwin, Olivia, Punjabi, Alkesh, and Ali, Halima

Subjects

*TOKAMAKS, *MAGNETIC fields, *ELECTROMAGNETIC induction, *MAGNETIC flux, *PHYSICS, *PLASMA gases

Abstract

A simple map [A. Punjabi, A. Verma, and A. Boozer, Phys. Rev. Lett. 69, 3322 (1992)] is the simplest map that has the topology of divertor tokamaks [A. Punjabi, H. Ali, T. Evans, and A. Boozer, Phys. Lett. A 364, 140 (2007)]. Here, action-angle coordinates, the safety factor, and the equilibrium generating function for the simple map are calculated analytically. The simple map in action-angle coordinates is derived from canonical transformations. This map cannot be integrated across the separatrix surface because of the singularity in the safety factor there. The stochastic broadening of the ideal separatrix surface in action-angle representation is calculated by adding a perturbation to the simple map equilibrium generating function. This perturbation represents the spatial noise and field errors typical of the DIII-D [J. L. Luxon and L. E. Davis, Fusion Technol. 8, 441 (1985)] tokamak. The stationary Fourier modes of the perturbation have poloidal and toroidal mode numbers (m,n,)={(3,1),(4,1),(6,2),(7,2),(8,2),(9,3),(10,3),(11,3)} with amplitude δ=0.8×10-5. Near the X-point, about 0.12% of toroidal magnetic flux inside the separatrix, and about 0.06% of the poloidal flux inside the separatrix is lost. When the distance from the O-point to the X-point is 1 m, the width of stochastic layer near the X-point is about 1.4 cm. The average value of the action on the last good surface is 0.19072 compared to the action value of 3/5π on the separatrix. The average width of stochastic layer in action coordinate is 2.7×10-4, while the average area of the stochastic layer in action-angle phase space is 1.69017×10-3. On average, about 0.14% of action or toroidal flux inside the ideal separatrix is lost due to broadening. Roughly five times more toroidal flux is lost in the simple map than in DIII-D for the same perturbation [A. Punjabi, H. Ali, A. Boozer, and T. Evans, Bull. Amer. Phys. Soc. 52, 124 (2007)]. [ABSTRACT FROM AUTHOR]

Published

2008

15. Transverse magnetic field effect on the transport of relativistic electrons beam in laser irradiating plasmas.

Author

Ya-Juan Hou, Chong Lv, Feng Wan, Nureli Yasen, Ali Bake, Muhammad, Hai-Bo Sang, and Bai-Song Xie

Subjects

*PLASMA gases, *LASER beams, *MAGNETIC fields, *ELECTRONS, *FIELD theory (Physics)

Abstract

A transverse gauss shape magnetic field with wide width is proposed for collimating the fast relativistic electron beam in laser irradiating plasmas, which is highlighted by the twodimensional particle-in-cell simulations, in particular, the effects of this magnetic field on the production and transport of fast electron beam. When the axial magnetic field is also present, it is found that the energy density of fast electrons can be enhanced greatly. For example, in the presence of 30MG axial magnetic field, it is enhanced by 3-4 times when the amplitude of the applied transverse magnetic field lies within the optimal regime 200-300MG comparable to that without the transverse magnetic field. Meanwhile, the divergence angle of the electron beam can be controlled and even decreased a little due to the better sandwich structure of the overall weakening magnetic field. The study implies that the proposed transverse magnetic field is helpful to obtain the high quality electron beam which is beneficial to the fast ignition in inertial confinement fusion. [ABSTRACT FROM AUTHOR]

Published

2017

16. Adiabatic trapping in coupled kinetic Alfvén-acoustic waves.

Author

Shah, H. A., Masood, W., and Ali, Z.

Subjects

*PLASMA Alfven waves, *ELECTRONS, *WAVELENGTHS, *MAGNETIC fields, *GEOMAGNETISM

Abstract

In the present work, we have discussed the effects of adiabatic trapping of electrons on obliquely propagating Alfvén waves in a low β plasma. Using the two potential theory and employing the Sagdeev potential approach, we have investigated the existence of arbitrary amplitude coupled kinetic Alfvén-acoustic solitary waves in both the sub and super Alfvénic cases. The results obtained have been analyzed and presented graphically and can be applied to regions of space where the low β assumption holds true. [ABSTRACT FROM AUTHOR]

Published

2013