Trade-oﬀ in perpendicular electric ﬁeld control using negatively biased emissive end-electrodes

Plasma Sources Science and Technology ◽

10.1088/1361-6595/ac4847 ◽

2022 ◽

Author(s):

Baptiste Trotabas ◽

Renaud Gueroult

Keyword(s):

Magnetic Field ◽

Electric Field ◽

Thermionic Emission ◽

Potential Drop ◽

Plasma Potential ◽

Magnetized Plasma ◽

Trade Off ◽

Sheath Edge ◽

Field Control ◽

Field Lines

Abstract The beneﬁts of thermionic emission from negatively biased electrodes for perpendicular electric ﬁeld control in a magnetized plasma are examined through its combined eﬀects on the sheath and on the plasma potential variation along magnetic ﬁeld lines. By increasing the radial current ﬂowing through the plasma thermionic emission is conﬁrmed to improve control over the plasma potential at the sheath edge compared to the case of a cold electrode. Conversely, thermionic emission is shown to be responsible for an increase of the plasma potential drop along magnetic ﬁeld lines in the quasi-neutral plasma. These results suggest that there exists a trade-oﬀ between electric ﬁeld longitudinal uniformity and amplitude when using negatively biased emissive electrodes to control the perpendicular electric ﬁeld in a magnetized plasma.

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Mapping of steady-state electric fields and convective drifts in geomagnetic fields – Part 1: Elementary models

Annales Geophysicae ◽

10.5194/angeo-34-55-2016 ◽

2016 ◽

Vol 34 (1) ◽

pp. 55-65 ◽

Cited By ~ 4

Author(s):

A. D. M. Walker ◽

G. J. Sofko

Keyword(s):

Magnetic Field ◽

Steady State ◽

Electric Field ◽

Electric Fields ◽

Magnetic Field Line ◽

Geomagnetic Field ◽

Geomagnetic Field Models ◽

Spatial Derivatives ◽

Field Lines ◽

The Magnetic Field

Abstract. When studying magnetospheric convection, it is often necessary to map the steady-state electric field, measured at some point on a magnetic field line, to a magnetically conjugate point in the other hemisphere, or the equatorial plane, or at the position of a satellite. Such mapping is relatively easy in a dipole field although the appropriate formulae are not easily accessible. They are derived and reviewed here with some examples. It is not possible to derive such formulae in more realistic geomagnetic field models. A new method is described in this paper for accurate mapping of electric fields along field lines, which can be used for any field model in which the magnetic field and its spatial derivatives can be computed. From the spatial derivatives of the magnetic field three first order differential equations are derived for the components of the normalized element of separation of two closely spaced field lines. These can be integrated along with the magnetic field tracing equations and Faraday's law used to obtain the electric field as a function of distance measured along the magnetic field line. The method is tested in a simple model consisting of a dipole field plus a magnetotail model. The method is shown to be accurate, convenient, and suitable for use with more realistic geomagnetic field models.

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Large linear magnetoelectric effect and field-induced ferromagnetism and ferroelectricity in DyCrO4

NPG Asia Materials ◽

10.1038/s41427-019-0151-9 ◽

2019 ◽

Vol 11 (1) ◽

Cited By ~ 3

Author(s):

Xudong Shen ◽

Long Zhou ◽

Yisheng Chai ◽

Yan Wu ◽

Zhehong Liu ◽

...

Keyword(s):

Magnetic Field ◽

Electric Field ◽

Spin Structure ◽

Magnetoelectric Effect ◽

Electric Polarization ◽

Metamagnetic Transition ◽

Ferromagnetic Component ◽

Antiferromagnetic Structure ◽

Field Control ◽

Ferromagnetic Magnetization

Abstract All the magnetoelectric properties of scheelite-type DyCrO4 are characterized by temperature- and field-dependent magnetization, specific heat, permittivity, electric polarization, and neutron diffraction measurements. Upon application of a magnetic field within ±3 T, the nonpolar collinear antiferromagnetic structure leads to a large linear magnetoelectric effect with a considerable coupling coefficient. An applied electric field can induce the converse linear magnetoelectric effect, realizing magnetic field control of ferroelectricity and electric field control of magnetism. Furthermore, a higher magnetic field (>3 T) can cause a metamagnetic transition from the initially collinear antiferromagnetic structure to a canted structure, generating a large ferromagnetic magnetization up to 7.0 μB f.u.−1. Moreover, the new spin structure can break the space inversion symmetry, yielding ferroelectric polarization, which leads to coupling of ferromagnetism and ferroelectricity with a large ferromagnetic component.

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A Look into Students' Interpretation of Electric Field Lines

Advances in Educational Technologies and Instructional Design - Handbook of Research on Driving STEM Learning With Educational Technologies ◽

10.4018/978-1-5225-2026-9.ch017 ◽

2017 ◽

pp. 342-364

Author(s):

Esmeralda Campos ◽

Genaro Zavala

Keyword(s):

Magnetic Field ◽

Electric Field ◽

Random Sample ◽

Qualitative Approach ◽

Undergraduate Level ◽

Field Lines

On Electricity & Magnetism (EM) courses at undergraduate level, the concept of electric field poses one of the most relevant and basic topics, along with the concept of magnetic field. Professors and students may use different diagrams as a tool to visualize the electric field, such as vectors or electric field lines. The present study aims to identify how students interpret and use electric field lines as a tool or resource to describe the electric field. Two versions of a test with open-ended questions were administered in Spanish in a private Mexican university to a random sample of students taking the EM course, and were analyzed with a qualitative approach. It was found that students do not interpret electric field lines diagrams correctly, which may lead to misconceptions. Many students based their answers on the concepts of superposition, force and repulsion.

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The occurrence frequency of auroral potential structures and electric fields as a function of altitude using Polar/EFI data

Annales Geophysicae ◽

10.5194/angeo-22-1233-2004 ◽

2004 ◽

Vol 22 (4) ◽

pp. 1233-1250 ◽

Cited By ~ 5

Author(s):

P. Janhunen ◽

A. Olsson ◽

H. Laakso

Keyword(s):

Electric Field ◽

High Altitude ◽

Electric Fields ◽

Radial Distance ◽

Plasma Potential ◽

Potential Structure ◽

New Finding ◽

Low Altitude ◽

Field Lines ◽

Auroral Arcs

Abstract. The aim of the paper is to study how auroral potential structures close at high altitude. We analyse all electric field data collected by Polar on auroral field lines in 1996–2001 by integrating the electric field along the spacecraft orbit to obtain the plasma potential, from which we identify potential minima by an automatic method. From these we estimate the associated effective mapped-down electric field Ei, defined as the depth of the potential minimum divided by its half-width in the ionosphere. Notice that although we use the ionosphere as a reference altitude, the field Ei does not actually exist in the ionosphere but is just a convenient computational quantity. We obtain the statistical distribution of Ei as a function of altitude, magnetic local time (MLT), Kp index and the footpoint solar illumination condition. Surprisingly, we find two classes of electric field structures. The first class consists of the low-altitude potential structures that are presumably associated with inverted-V regions and discrete auroral arcs and their set of associated phenomena. We show that the first class exists only below ~3RE radial distance, and it occurs in all nightside MLT sectors (RE=Earth radius). The second class exists only above radial distance R=4RE and almost only in the midnight MLT sector, with a preference for high Kp values. Interestingly, in the middle altitudes (R=3–4RE) the number of potential minima is small, suggesting that the low and high altitude classes are not simple field-aligned extensions of each other. This is also underlined by the fact that statistically the high altitude structures seem to be substorm-related, while the low altitude structures seem to correspond to stable auroral arcs. The new finding of the existence of the two classes is important for theories of auroral acceleration, since it supports a closed potential structure model for stable arcs, while during substorms, different superposed processes take place that are associated with the disconnected high-altitude electric field structures. Key words. Magnetospheric physics (electric fields; auroral phenomena) – Space plasma physics (electrostatic structures)

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Effect of permanent magnets on plasma confinement and ion beam properties in a double layer helicon plasma source

Journal of Plasma Physics ◽

10.1017/s0022377819000412 ◽

2019 ◽

Vol 85 (3) ◽

Author(s):

Erik Varberg ◽

Åshild Fredriksen

Keyword(s):

Magnetic Field ◽

Permanent Magnets ◽

Ion Beam ◽

Plasma Source ◽

Diffusion Chamber ◽

Plasma Potential ◽

Field Energy ◽

Plasma Confinement ◽

Plasma Device ◽

Field Lines

The work described in this article was carried out to investigate how permanent magnets (PM) affect the plasma confinement and ion beam properties in an inductively coupled plasma which expands from a helicon source. The cylindrical plasma device Njord has a 13 cm long and 20 cm wide stainless steel port connecting the source chamber and the diffusion chamber. The source chamber has an axial magnetic field produced by two coils, with magnetic field lines expanding into the diffusion chamber. Simulations have shown that the field lines leaving the edge of the source hit the port wall, causing a loss of electrons in this section. In the experiments performed in this work, PMs were added around the port walls near the exit of a plasma source and the effect was investigated experimentally by means of a retarding field energy analyser probe. The plasma potential, ion density and ion beam parameters were estimated, and the results with and without the PMs were compared. The results showed that the plasma density in the centre can in some cases be doubled, and the density at the edges of the plasma increased significantly with PMs in place. Although the plasma potential was slightly affected, and the beam velocity dropped by ${\sim}$ 10 %, the ion beam flux increased by a factor of 1.5.

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Very High-Energy Emission from the Direct Vicinity of Rapidly Rotating Black Holes

Galaxies ◽

10.3390/galaxies6040122 ◽

2018 ◽

Vol 6 (4) ◽

pp. 122 ◽

Cited By ~ 3

Author(s):

Kouichi Hirotani

Keyword(s):

Magnetic Field ◽

Black Holes ◽

Black Hole ◽

Electric Field ◽

Gamma Rays ◽

Accretion Rate ◽

High Energy ◽

Relativistic Electrons ◽

Field Lines ◽

The Magnetic Field

When a black hole accretes plasmas at very low accretion rate, an advection-dominated accretion flow (ADAF) is formed. In an ADAF, relativistic electrons emit soft gamma-rays via Bremsstrahlung. Some MeV photons collide with each other to materialize as electron-positron pairs in the magnetosphere. Such pairs efficiently screen the electric field along the magnetic field lines, when the accretion rate is typically greater than 0.03–0.3% of the Eddington rate. However, when the accretion rate becomes smaller than this value, the number density of the created pairs becomes less than the rotationally induced Goldreich–Julian density. In such a charge-starved magnetosphere, an electric field arises along the magnetic field lines to accelerate charged leptons into ultra-relativistic energies, leading to an efficient TeV emission via an inverse-Compton (IC) process, spending a portion of the extracted hole’s rotational energy. In this review, we summarize the stationary lepton accelerator models in black hole magnetospheres. We apply the model to super-massive black holes and demonstrate that nearby low-luminosity active galactic nuclei are capable of emitting detectable gamma-rays between 0.1 and 30 TeV with the Cherenkov Telescope Array.

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Particle acceleration by interstellar plasma shock waves in non-uniform background magnetic field

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/staa2768 ◽

2020 ◽

Vol 498 (4) ◽

pp. 5517-5523

Author(s):

P Rashed-Mohassel ◽

M Ghorbanalilu

Keyword(s):

Magnetic Field ◽

Particle Acceleration ◽

Shock Waves ◽

Electric Field ◽

Background Field ◽

Magnetized Plasma ◽

Background Magnetic Field ◽

Positive Variation ◽

Uniform Background ◽

Plasma Shock

ABSTRACT Particle acceleration by plasma shock waves is investigated for a magnetized plasma cloud propagating in a non-uniform background magnetic field by means of analytical and numerical calculations. The mechanism studied here is mainly, magnetic trapping acceleration (MTA) which is previously investigated for a cloud moving through the uniform interstellar magnetic field (IMF). In this work, the acceleration is studied for a cloud moving in an antiparallel background field with spatial variations along the direction of motion. For negative variation, the cloud moves towards an antiparallel magnetic field with an increasing intensity, the trapped particle moves to locations with higher convective electric field and therefore gains more energy over time. For positive variation, the background field decreases to zero and changes into a parallel field with an increasing intensity. It is concluded that, when the background field vanishes, the MTA mechanism ceases and the particle escapes into the space. This leads to a bouncing acceleration which further increases energy of the gyrating particle. The two processes are followed by a shock drift acceleration, where due to the background magnetic field gradient, the particle drifts along the electric field and gains energy. Although for positive variation, three different mechanisms are involved, energy gain is less than in the case of a uniform background field.

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Plasma Potential Formation and Particle Acceleration Due to ECRH in Diverging Magnetic-Field Lines

Fusion Technology ◽

10.13182/fst99-a11963877 ◽

1999 ◽

Vol 35 (1T) ◽

pp. 325-329 ◽

Cited By ~ 1

Author(s):

Rikizo Hatakeyama ◽

Toshiro Kaneko ◽

Noriyoshi Sato

Keyword(s):

Magnetic Field ◽

Particle Acceleration ◽

Plasma Potential ◽

Potential Formation ◽

Field Lines

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Excitation Magnetohydrodynamic Wave by Gravitational Wave Produced by Binary of Neutron Stars

International Journal of Modern Physics Conference Series ◽

10.1142/s2010194517600060 ◽

2017 ◽

Vol 45 ◽

pp. 1760006

Author(s):

Adam S. Gontijo ◽

Oswaldo D. Miranda

Keyword(s):

Magnetic Field ◽

Neutron Stars ◽

Gravitational Wave ◽

Acoustic Mode ◽

Magnetized Plasma ◽

Uniform Field ◽

Pressure Gradients ◽

Magnetohydrodynamic Wave ◽

Field Lines ◽

The Magnetic Field

The gravitational wave, through the strongly magnetized plasma surrounding the neutron stars, in the [Formula: see text]-direction, deforms plasma particle rings in ellipses, alternating axes periodically along the direction of the magnetic field ([Formula: see text]-axis) and of the [Formula: see text]-axis. The uniform field leads to a modulation of the magnetic field, which results in magnetic pressure gradients (magneto-acoustic mode) or in the shear of the magnetic field lines (Alfvén mode). The gravitational wave drives MHD modes and transfers energy to the plasma, can become an important alternative process for the acceleration of baryons to high Lorentz factors observed in short GRBs. The total amount of energy that is transferred from the gravitational wave to the plasma is estimated ([Formula: see text]J - [Formula: see text] J), with [Formula: see text]. We compare our results with previously obtained results by other works.

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