Variable gaseous ion beams from plasmas driven by electromagnetic waves for nano-micro structuring: a tutorial and an overview of recent works and future prospects

Maurya, Sanjeev Kumar; Bhattacharjee, Sudeep

doi:10.1088/2516-1067/aba07c

Cited by 3 publications

(1 citation statement)

References 87 publications

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“…There are many types of plasma-based devices that have or can have multipolar magnetic fields (e.g., produced by permanent magnets) along a plasma-facing wall. Examples include the multipurpose device called the Big Red Ball, 22,23 high efficiency multistage plasma thrusters for space propulsion, 24 ion sources for charged particle beams, 25 plasma chambers for processing materials, 26,27 and other plasma confinement and control systems for studies of plasma phenomena. [28][29][30][31] Such devices may benefit from enhanced plasma confinement, which may be possible by incorporating plasmaimmersed magnetic coils.…”

Section: Introductionmentioning

confidence: 99%

Magnetic confinement of effectively unmagnetized plasma particles

Ordonez

2020

Physics of Plasmas

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A purely magnetic applied field may provide plasma confinement under conditions where the bulk of the plasma is effectively free of the applied magnetic field. The applied magnetic field surrounds the bulk of the plasma, and plasma particles that are incident on the applied magnetic field can be reflected back into the effectively unmagnetized region of plasma. The concept belongs to a class of magnetic plasma confinement approaches studied long ago, for which some experimental results indicated that classical (collision-based) cross-magnetic-field transport may occur. However, multiple magnetic coils are required to be immersed within the confined plasma, and rapid plasma loss may occur if material structures are present, which pass through the plasma (e.g., to hold the immersed coils in place). In the work reported, the concept is studied in combination with magnetic plasma expulsion [R. E. Phillips and C. A. Ordonez, Phys. Plasmas 25, 012508 ( 2018)], which would be employed to keep plasma away from material structures that pass through the plasma. A planar model is used for the study. A classical trajectory Monte Carlo simulation is carried out on particles that are independently incident on the applied magnetic field. With monoenergetic incident particles, the results indicate that the applied magnetic field can reflect all independently incident particles in certain regions of parameter space. Prospects for achieving three-dimensional magnetic confinement of an effectively unmagnetized plasma with a Maxwellian velocity distribution are discussed.

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Section: Introductionmentioning

confidence: 99%

Magnetic confinement of effectively unmagnetized plasma particles

Ordonez

2020

Physics of Plasmas

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Experimental realization of nonlinear demagnification in plasma-based charged particle optics

Barman

Maurya

Bhattacharjee

2022

Plasma Res. Express

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We experimentally demonstrate nonlinear demagnification (DM) in plasma-based charged particle optics. The nonlinearity originates from the non-uniform penetration of electric fields through the plasma sheath region, when the object beam size (dP ) is reduced to below the Debye length (λ d ). The strength of nonlinearity depends upon dP and λ d , as confirmed from experimental results and a theoretical model. Nonlinear DM is unique to optics of classical Maxwell-Boltzmann systems and unrealized in conventional liquid metal sources where the Fermi Debye length » dP . The realization of plasma sheaths being able to control DM can greatly enhance the performance of charged particle optical systems.

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Electron Capture by Proton Beam in Collisions with Water Vapor

Maurya

Bhogale

Tribedi

2023

Atoms

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In low energy ion-molecule collisions, electron capture is one of the most important channels. A new experimental setup was developed to study the electron capture process using low-energy ion beams extracted from an electron cyclotron resonance (ECR) plasma-based ion accelerator. Experiments were carried out with the proton beam colliding with water vapor in the energy range of 70–300 keV. Capture events were detected using a position-sensitive detection system comprising micro channel plates (MCPs) and a delay line detector (DLD). These e-capture events can be a result of pure capture reactions as well as transfer ionization. The capture cross section was found to decrease sharply with the beam energy and agreed well with previous measurements. The setup was also used to detect the events that gave rise to the single and multiple e-capture (integrated over all recoil-ion charge states) of C4+ ions. The capture cross-sections for one, two, three, and four electrons were measured for 100 keV C4+ ions. The ratio of multielectron capture yield to that for single e-capture decreased with the number of captured electrons.

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Variable gaseous ion beams from plasmas driven by electromagnetic waves for nano-micro structuring: a tutorial and an overview of recent works and future prospects

Cited by 3 publications

References 87 publications

Magnetic confinement of effectively unmagnetized plasma particles

Magnetic confinement of effectively unmagnetized plasma particles

Experimental realization of nonlinear demagnification in plasma-based charged particle optics

Electron Capture by Proton Beam in Collisions with Water Vapor

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