Low-temperature M = 3 flow deceleration by Lorentz force

This paper presents results of cold magnetohydrodynamic (MHD) flow deceleration experiments using repetitively pulsed, short pulse duration, high voltage discharge to produce ionization in M = 3 nitrogen and air flows in the presence of transverse direct current electric field and transverse magneti...

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Bibliographic Details
Published in:Physics of fluids (1994) 2006-08, Vol.18 (8), p.086101-086101-11
Main Authors: Nishihara, Munetake, Rich, J. William, Lempert, Walter R., Adamovich, Igor V., Gogineni, Sivaram
Format: Article
Language:English
Subjects:
ACCELERATION
AIR FLOW
CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS
DIRECT CURRENT
ELECTRIC DISCHARGES
ELECTRIC FIELDS
EQUATIONS
Exact sciences and technology
Fluid dynamics
Fundamental areas of phenomenology (including applications)
Instrumentation for fluid dynamics
IONIZATION
JOULE HEATING
LORENTZ FORCE
MACH NUMBER
MAGNETIC FIELDS
MAGNETOHYDRODYNAMICS
Magnetohydrodynamics and electrohydrodynamics
NITROGEN
ONE-DIMENSIONAL CALCULATIONS
Physics
Physics of gases, plasmas and electric discharges
Physics of plasmas and electric discharges
PLASMA
Plasma macroinstabilities (hydromagnetic, eg, kink, fire-hose, mirror, ballooning, tearing, trapped-particle, flute, Rayleigh-Taylor, etc.)
Plasma macroinstabilities (magnetohydrodynamic, e.g., kink, fire-hose, mirror, ballooning, tearing, trapped-particle, flute, rayleigh-taylor, etc.)
PRESSURE MEASUREMENT
SIMULATION
SUPERSONIC FLOW
Waves, oscillations, and instabilities in plasmas and intense beams
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Summary:This paper presents results of cold magnetohydrodynamic (MHD) flow deceleration experiments using repetitively pulsed, short pulse duration, high voltage discharge to produce ionization in M = 3 nitrogen and air flows in the presence of transverse direct current electric field and transverse magnetic field. MHD effect on the flow is detected from the flow static pressure measurements. Retarding Lorentz force applied to the flow produces a static pressure increase of up to 17%–20%, while accelerating force of the same magnitude results in static pressure increase of up to 5%–7%. The measured static pressure changes are compared with modeling calculations using quasi-one-dimensional MHD flow equations. Comparison of the experimental results with the modeling calculations shows that the retarding Lorentz force increases the static pressure rise produced by Joule heating of the flow, while the accelerating Lorentz force reduces the pressure rise. The effect is produced for two possible combinations of the magnetic field and transverse current directions producing the same Lorentz force direction (both for accelerating and retarding force). This demonstrates that the observed static pressure change is indeed due to the MHD interaction, and not due to Joule heating of the flow in the crossed discharge. No discharge polarity effect on the static pressure was detected in the absence of the magnetic field. The fraction of the discharge input power going into Joule heat in nitrogen and dry air, inferred from the present experiments, is low, α = 0.1 , primarily because energy remains frozen in the vibrational energy mode of nitrogen. This result provides first direct evidence of cold supersonic flow deceleration by Lorentz force.
ISSN:1070-6631
1089-7666
DOI:10.1063/1.2265011