2004
DOI: 10.1088/0963-0252/13/4/014
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Measurement of the magnetic field change in a pulsed high current magnetron discharge

Abstract: In this paper we present a study of how the magnetic field of a circular planar magnetron is affected when it is exposed to a pulsed high current discharge. Spatially resolved magnetic field measurements are presented and the magnetic disturbance is quantified for different process parameters. The magnetic field is severely deformed by the discharge and we record changes of several millitesla, depending on the spatial location of the measurement. The shape of the deformation reveals the presence of azimuthally… Show more

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Cited by 71 publications
(111 citation statements)
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“…Following the time-evolution of the internal currents it is seen in the middle panel of times the discharge current (~300-350 A) compared to the present investigation (60 A) [11]. The left panel of Figure 3a shows slightly less than a quarter of that value, which is consistent with our lower discharge current.…”
Section:  supporting
confidence: 88%
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“…Following the time-evolution of the internal currents it is seen in the middle panel of times the discharge current (~300-350 A) compared to the present investigation (60 A) [11]. The left panel of Figure 3a shows slightly less than a quarter of that value, which is consistent with our lower discharge current.…”
Section:  supporting
confidence: 88%
“…It might be that both the azimuthal and the cross-B current are increasingly concentrated in the region above the race track because the plasma density still rises there. Similar double peak structures were observed by Bohlmark et al [11] when investigating time-dependent variations of the magnetic field on the same device. The authors ascribe this phenomenon as related to an interplay between the electric field (-z) and the plasma pressure (+z), where the electric field is strongly reduced in the decay phase of the HiPIMS pulse, and thereby causing an expansion of the dense plasma torus.…”
Section: Current Configurationsupporting
confidence: 86%
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“…The analytical fits used in the model are shown in figure 4(a). As standard parameters in the model we use r 1 = 2 cm, r 2 = 7 cm (based on the racetrack erosion area), z 1 = 0.1 cm (based on estimates of the sheath thickness) and z 2 = 3 cm (based on plasma density measurements in the same device by Bohlmark et al [17]). Figure 4(b) shows that quite a good current fit is already obtained with a time independent F PWR = 0.273.…”
Section: Results From Model Runsmentioning
confidence: 99%
“…[4,16,17]), but for this rough estimate the classical formula is assumed to hold in the azimuthal direction. The ionization coefficient k ion is evaluated using the following expressions [18,19] for the rate coefficients As concerns the excitation de-excitation term neglected in (4), a crude estimate of the rate coefficient (−k exc + k dexc n Ar * /n Ar ) can be carried out using a simple steady state balance for Ar* dn Ar * dt = 0 = k exc n e n Ar − k iz,Ar * n e n Ar * − k dexc n e n Ar * − k p n e n Ar * n Ar * = k exc k dexc + k p + k ion,Ar * that plugged into the neglected term in the first line of (4) gives…”
Section: Appendix a Determination Of The Physical Parametersmentioning
confidence: 99%