Electron cooling and finite potential drop in a magnetized plasma expansion

Martı́nez-Sánchez, Manuel; Navarro-Cavallé, Jaume; Ahedo, Eduardo

doi:10.1063/1.4919627

Cited by 57 publications

(103 citation statements)

References 16 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The electrons responsible for the adiabatic expansion produce spatial changes in the slope of the downward 1D eepfs along the axial direction, relating γ e closer to 5/3 near the nozzle throat. In comparison to the adiabatic electrons, the newly observed electrons measured by the back probe, which cannot be explained by adiabatic cooling, can be classified into groups of free and confined electrons according to their energy and magnetic moment values [27]. For electrons, the local maximum magnetic moment μ e,m (z, E e ) with total energy E e can be expressed as follows: μ e,m (z, E e )=(E e +ef(z))/B z , where the axial variation of the plasma potential f(z) is calculated using the average knee of measured I-V characteristics with front and back probe.…”

Section: Correlation Between the Bounce Region Of Confined Electrons mentioning

confidence: 99%

“…The polytropic exponent γ e in the equation describes the exchange of heat between a magnetically expanding plasma and the system, and various kinetic modeling approaches have been established to explore the physical meaning of MN devices by relating the thermodynamic model to the MN phenomena, e.g. plasma detachment, plume divergence efficiency, and thruster gain [26][27][28][29][30][31].…”

Section: Introductionmentioning

confidence: 99%

“…Theoretically, kinetic approaches to the motion of electron and ion in the MN system divide the electrons into several groups according to their magnetic moment and total energy with a given plasma potential and magnetic field structure in the MN [27]. The model assumed the conservation of the adiabatic invariants of the electrons in a decreasing plasma potential that eventually tended to asymptotic values with non-isothermal cases as bounded plasma in magnetically diverging structure.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Thermodynamics of a magnetically expanding plasma with isothermally behaving confined electrons

Kim

Ryu

et al. 2018

New J. Phys.

View full text Add to dashboard Cite

Thermodynamics of a magnetically expanding plasma (magnetic nozzle (MN)) has been investigated considering the existence of confined electrons bouncing back and forth inside a potential well formed by a combination of external magnetic field and self-generating ambipolar electrostatic potential. The properties of confined electrons are distinguished from that of the adiabatically expanding electrons with γ e ≈5/3 by the separate measurement of each species using a double-sided planar Langmuir probe. Relationship between the electron pressure versus electron density averaged over electron energy probability functions (eepfs) clearly reveals that the confined electrons in MN have a nearly isothermal characteristic. Existence of isothermally behaving confined electrons together with adiabatically expanding electrons separates the MN system into two regions with different thermodynamic properties; one is a nearly adiabatic region located near the nozzle throat and the other is nearly isothermal region located far from the nozzle. A transition of electron thermodynamic property along a distance from the nozzle throat can be explained with conservation of magnetic moment of electrons bounced back by ambipolar electrostatic potential. Coexistence of the nearly adiabatic electrons with Maxwellian eepf and the nearly isothermal electrons with high energydepleted eepf makes the overall eepf shape low energy-populated eepf, indicating a need for careful analysis on the measured eepfs near the nozzle throat. In spite of significant contribution of confined electrons to eepf and overall electron thermodynamics, it is found that the confined electrons behaving isothermally do not contribute to the generation of ambipolar electrostatic potential which is important for ion acceleration in MN. The present study suggests that ion acceleration should not be directly inferred from the value of polytropic exponent γ e because thermodynamic property of a MN is influenced by isothermally behaving confined electrons as well as adiabatically expanding electrons.

show abstract

Section: Correlation Between the Bounce Region Of Confined Electrons mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Thermodynamics of a magnetically expanding plasma with isothermally behaving confined electrons

Kim

Ryu

et al. 2018

New J. Phys.

View full text Add to dashboard Cite

show abstract

“…Luckily, the plasma plumes of electric thrusters (in particular, their far-region) present several advantageous characteristics, such as axisymmetry and moderate divergence, that can be exploited to set up a nearlyanalytical kinetic model. In a previous study, 40,41 a steady-state 1D-2V kinetic model based on the conservation of energy and the quasi-conservation of the magnetic moment of each electron in a strong convergentdivergent magnetic field (i.e., a magnetic nozzle 42,43 ), which improved on a previous non-stationary model by Arefiev and Breizman, 44 was established and used to compute the evolution of electron temperature in the collisionless plasma and derive simple closure relations that can be used to inform fluid electron models. The success of that model for a similar, related problem encourages us to follow a similar approach for the case of interest here (an unmagnetized plasma plume).…”

Section: Introductionmentioning

confidence: 91%

“…In the absence of a better criterion at present, and following the choice taken in Ref. 40,41, it can be assumed that after sufficiently long periods of time these regions are populated by the same distribution function as the plasma source electrons (or, alternatively a fixed fraction density of it to study the effect of these regions being only partially filled).…”

Section: B Evolution Of the Distribution Function Of A Collisionlessmentioning

confidence: 99%

Collisionless electron cooling in unmagnetized plasma thruster plumes

Merino¹,

Fajardo²,

Ahedo³

2016

52nd AIAA/SAE/ASEE Joint Propulsion Conference

View full text Add to dashboard Cite

A kinetic model of electrons in a steady-state, collisionless, paraxial plasma plume is presented. The model is based on the conservation of an adiabatic invariant related to the oscillating radial motion of the electrons in the electric potential of the plume. The electron phase space can be divided into distinct regions according to their connectivity with the upstream or downstream boundary conditions, and may include isolated regions of trapped electrons. A particular plasma potential is used to illustrate the capabilities of the model. This electron model is the first and fundamental piece of a full plasma plume model that will allow the self-consistent computation of the ion, electron, and electric potential responses in order to investigate electron collisionless cooling mechanisms in an unmagnetized plasma plume.

show abstract

Design and In-orbit Demonstration of REGULUS, an Iodine electric propulsion system

et al. 2021

View full text Add to dashboard Cite

REGULUS is an Iodine-based electric propulsion system. It has been designed and manufactured at the Italian company Technology for Propulsion and Innovation SpA (T4i). REGULUS integrates the Magnetically Enhanced Plasma Thruster (MEPT) and its subsystems, namely electronics, fluidic, and thermo-structural in a volume of 1.5 U. The mass envelope is 2.5 kg, including propellant. REGULUS targets CubeSat platforms larger than 6 U and CubeSat carriers. A thrust T = 0.60 mN and a specific impulse Isp = 600 s are achieved with an input power of P = 50 W; the nominal total impulse is Itot = 3000 Ns. REGULUS has been integrated on-board of the UniSat-7 satellite and its In-orbit Demonstration (IoD) is currently ongoing. The principal topics addressed in this work are: (i) design of REGULUS, (ii) comparison of the propulsive performance obtained operating the MEPT with different propellants, namely Xenon and Iodine, (iii) qualification and acceptance tests, (iv) plume analysis, (v) the IoD.

show abstract

Electron cooling and finite potential drop in a magnetized plasma expansion

Cited by 57 publications

References 16 publications

Thermodynamics of a magnetically expanding plasma with isothermally behaving confined electrons

Thermodynamics of a magnetically expanding plasma with isothermally behaving confined electrons

Collisionless electron cooling in unmagnetized plasma thruster plumes

Design and In-orbit Demonstration of REGULUS, an Iodine electric propulsion system

Contact Info

Product

Resources

About