Your search keyword '"Electromagnetic fields."' showing total 5 results

1. Artificially Structured Boundary for Control and Confinement of Beams and Plasmas

Author

Hedlof, Ryan

Subjects

plasma physics, computational physics, antimatter, Physics, Fluid and Plasma, Physics, Electricity and Magnetism, Electromagnetic fields., Plasma (Ionized gases), Antimatter., Positrons., Particle beams.

Abstract

An artificially structured boundary (ASB) produces a short-range, static electromagnetic field that can reflect charged particles. In the work presented, an ASB is considered to consist of a spatially periodic arrangement of electrostatically plugged magnetic cusps. When used to create an enclosed volume, an ASB may confine a non-neutral plasma that is effectively free of applied electromagnetic fields, provided the spatial period of the ASB-applied field is much smaller than any one dimension of the confinement volume. As envisioned, a non-neutral positron plasma could be confined by an ASB along its edge, and the space-charge of the positron plasma would serve to confine an antiproton plasma. If the conditions of the two-species plasma are suitable, production of antihydrogen via three-body recombination for antimatter gravity studies may be possible. A classical trajectory Monte Carlo (CTMC) simulation suite has been developed in C++ to efficiently simulate charged particle interactions with user defined electromagnetic fields. The code has been used to explore several ASB configurations, and a concept for a cylindrically symmetric ASB trap that employs a picket-fence magnetic field has been developed. Particle-in-cell (PIC) modeling has been utilized to investigate the confinement of non-neutral and partially neutralized positron plasmas in the trap.

Published

2018

2. An Electro- Magneto-static Field for Confinement of Charged Particle Beams and Plasmas

Author

Pacheco, Josè L.

Subjects

Ion trap, artificially structured boundary, plasma confinement, ion beam guide, ion source, Particle beams., Plasma dynamics., Electromagnetic fields.

Abstract

A system is presented that is capable of confining an ion beam or plasma within a region that is essentially free of applied fields. An Artificially Structured Boundary (ASB) produces a spatially periodic set of magnetic field cusps that provides charged particle confinement. Electrostatic plugging of the magnetic field cusps enhances confinement. An ASB that has a small spatial period, compared to the dimensions of a confined plasma, generates electro- magneto-static fields with a short range. An ASB-lined volume thus constructed creates an effectively field free region near its center. It is assumed that a non-neutral plasma confined within such a volume relaxes to a Maxwell-Boltzmann distribution. Space charge based confinement of a second species of charged particles is envisioned, where the second species is confined by the space charge of the first non-neutral plasma species. An electron plasma confined within an ASB-lined volume can potentially provide confinement of a positive ion beam or positive ion plasma. Experimental as well as computational results are presented in which a plasma or charged particle beam interact with the electro- magneto-static fields generated by an ASB. A theoretical model is analyzed and solved via self-consistent computational methods to determine the behavior and equilibrium conditions of a relaxed plasma. The equilibrium conditions of a relaxed two species plasma are also computed. In such a scenario, space charge based electrostatic confinement is predicted to occur where a second plasma species is confined by the space charge of the first plasma species. An experimental apparatus with cylindrical symmetry that has its interior surface lined with an ASB is presented. This system was developed by using a simulation of the electro- magneto-static fields present within the trap to guide mechanical design. The construction of the full experimental apparatus is discussed. Experimental results that show the characteristics of electron beam transmission through the experimental apparatus are presented. A description of the experimental hardware and software used for trapping a charged particle beam or plasma is also presented.

Published

2014

3. Anatomically-tailored magnetic resonance radio frequency probes

Author

De Zanche, Nicola

Subjects

Nuclear magnetic resonance., Electromagnetic fields., Molecular probes.

Published

2002

4. Investigations on the quantization of spin 3/2 field

Author

Soo, Wing-Fatt

Subjects

Electromagnetic fields., Rotational motion., Mathematical physics.

Published

1974

5. The perturbation of an alternating electromagnetic field by two-dimensional conductivity models in a cylindrical co-ordinate system

Author

Tatrallyay, Mariella

Subjects

Electromagnetic fields., Perturbation (Mathematics), Electromagnetic devices. Mathematical models., Electromagnetism. Mathematical models., Polarization (Electricity), Physics. Research.

Published

1974