Measurements of the sheath potential in low density plasmas

Bradley, James W.; Khamis, Raad A.; Sanduk, Mohammed; Elliott, J A; Rusbridge, M G

doi:10.1088/0022-3727/25/10/009

Cited by 14 publications

(10 citation statements)

References 11 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The space resolution is limited by the size of the probe including its sheath; a resolution of 1 mm has been demonstrated. 40 Emissive probes have been successfully applied to measure plasma potentials in a wide range of magnetic fields, from tens of mT for a quadrupole device 41 to 0.5 T at the edge of a Tokamak 38 or Q-machine. 42 It should be noted that the emitted electrons have energies of about 0.3 eV, corresponding to a wire temperature of 3000 K w T  .…”

Section: Emissive Probe Techniquesmentioning

confidence: 99%

Plasma potential mapping of high power impulse magnetron sputtering discharges

Rauch

Mendelsberg

Sanders

et al. 2012

Journal of Applied Physics

View full text Add to dashboard Cite

Pulsed emissive probe techniques have been used to determine the plasma potential distribution of high power impulse magnetron sputtering (HiPIMS) discharges. An unbalanced magnetron with a niobium target in argon was investigated for pulse length of 100 µs at a pulse repetition rate of 100 Hz, giving a peak current of 170 A. The probe data were taken with a time resolution of 20 ns and a spatial resolution of 1 mm. It is shown that the local plasma potential varies greatly in space and time. The lowest potential was found over the target's racetrack, gradually reaching anode potential (ground) several centimeters away from the target. The magnetic pre-sheath exhibits a funnel-shaped plasma potential resulting in an electric field which accelerates ions toward the racetrack. In certain regions and times, the potential exhibits weak local maxima which allow for ion acceleration to the substrate. Knowledge of the local E and static B fields lets us derive the electrons' E × B drift velocity, which is about 10 5 m/s and shows structures in space and time.

show abstract

Section: Emissive Probe Techniquesmentioning

confidence: 99%

Plasma potential mapping of high power impulse magnetron sputtering discharges

Rauch

Mendelsberg

Sanders

et al. 2012

Journal of Applied Physics

View full text Add to dashboard Cite

show abstract

“…Using the direct measurement of the upstream floating potential and evaluating the plasma potential using the second derivative of the Langmuir probe characteristic [15], we obtain α = 1.7, considerably less than that expected for an isotropic plasma. Supersonic ion flow will tend to reduce the value of α and a more detailed analysis [10,13,16,17] suggests a full expression for α:…”

Section: Upstream Plasma Beam Characteristicsmentioning

confidence: 99%

The interaction of a flowing plasma with a dipole magnetic field: measurements and modelling of a diamagnetic cavity relevant to spacecraft protection

Bamford

Gibson

Thornton

et al. 2008

Plasma Phys. Control. Fusion

View full text Add to dashboard Cite

Here we describe a new experiment to test the shielding concept of a dipolelike magnetic field and plasma, surrounding a spacecraft forming a 'mini magnetosphere'. Initial laboratory experiments have been conducted to determine the effectiveness of a magnetized plasma barrier to be able to expel an impacting, low beta, supersonic flowing energetic plasma representing the solar wind. Optical and Langmuir probe data of the plasma density, the plasma flow velocity and the intensity of the dipole field clearly show the creation of a narrow transport barrier region and diamagnetic cavity virtually devoid of energetic plasma particles. This demonstrates the potential viability of being able to create a small 'hole' in a solar wind plasma, of the order of the ion Larmor orbit width, in which an inhabited spacecraft could reside in relative safety. The experimental results have been quantitatively compared with a 3D particle-incell 'hybrid' code simulation that uses kinetic ions and fluid electrons, showing good qualitative agreement and excellent quantitative agreement. Together the results demonstrate the pivotal role of particle kinetics in determining generic plasma transport barriers.

show abstract

“…The plasma density profile has a maximum near the separatrix and falls to a low value at the critical surface. Close to the separatrix there is a fast-moving plasma stream with drift speed about 2 × 10 4 m s −1 , bounded by a steep velocity shear layer at ψ/I Q = 0.04; the outer plasma which carries the drift waves is cool (T e ≈ 1 eV) and drifts slowly away from the source at a speed of the order of 1000 m s −1 (Bradley et al 1992). This is less than, but comparable to, the diamagnetic drift speed, so allowance for the Doppler shift is required in comparing the experimental and theoretical dispersion curves.…”

Section: Drift Waves In Goluxmentioning

confidence: 99%

Experiments on drift wave launching: I. Dispersion curves and damping rates

Sandeman

Uddholm

Elliott

et al. 1997

Plasma Phys. Control. Fusion

Self Cite

View full text Add to dashboard Cite

We describe experiments on the launching of drift waves in the UMIST Quadrupole GOLUX, presenting the general principles of successful launching and showing how these are applied to launch both the unstable drift waves which occur spontaneously in the device, and other stable modes representing different branches of the drift wave dispersion relation. In each case the measured dispersion curves are presented and compared with theory. All the waves appear to be spatially damped, including those known to be unstable; we propose that this is due to systematic error in the detection system. The results suggest that only if the measured decay constant exceeds about 8 m −1 can we be certain that the waves are actually damped. This is the case at low frequencies, where the dissipation is due to ion Landau damping, and again at high wavenumbers where no suitable dissipative process has been discovered. We conjecture that the effect is due to radiative damping, associated with the breakdown of the one-dimensional propagation assumed in the theory.

show abstract

Measurements of the sheath potential in low density plasmas

Cited by 14 publications

References 11 publications

Plasma potential mapping of high power impulse magnetron sputtering discharges

Plasma potential mapping of high power impulse magnetron sputtering discharges

The interaction of a flowing plasma with a dipole magnetic field: measurements and modelling of a diamagnetic cavity relevant to spacecraft protection

Experiments on drift wave launching: I. Dispersion curves and damping rates

Contact Info

Product

Resources

About