Afterglow dynamics of plasma potential in bipolar HiPIMS discharges

Avino, Fabio; Manke, F.; Richard, Thibault; Sublet, A.

doi:10.1088/1361-6595/ac2aed

Cited by 8 publications

(26 citation statements)

References 28 publications

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“…As reported by Avino et al [50], recently, a local net negative charge and consequent plasma potential drop appear in front of the target centre after applying the positive pulse for ∼30 μs, obtained by PIC-MCC simulation. When this larger potential drop appears close to the target, the ionization events may occur, resulting in the formation of the anode glow and plasma double layer [50,51]. Therefore, in the present work for ACBP-HiPIMS discharge with an auxiliary anode, we believe that the potential distribution along z-direction is in favour of plasma double layer shown in figure 8(b) (blue line), instead of the electron sheath and anode glow, as deduced via the following evidences:…”

Section: Double Layer Potential In Acbp-supporting

confidence: 70%

“…This implies that increasing the strength of the coil magnetic field speeds up the re-distribution of plasma potential structure. As reported in [27,31,33,50] for the regular BP-HiPIMS discharge, a double layer potential structure was found or inferred, which was considered as the critical structure to accelerate ions. However, in [27], this double layer potential only appears at the beginning of the positive pulse with a short-life time.…”

Section: Double Layer Potential In Acbp-mentioning

confidence: 54%

“…Figure 8(b) shows three possible plasma potential V p distributions in z-direction, including the so-called electron sheath, anode glow and plasma double layer, according to [31]. As reported by Avino et al [50], recently, a local net negative charge and consequent plasma potential drop appear in front of the target centre after applying the positive pulse for ∼30 μs, obtained by PIC-MCC simulation. When this larger potential drop appears close to the target, the ionization events may occur, resulting in the formation of the anode glow and plasma double layer [50,51].…”

Section: Double Layer Potential In Acbp-mentioning

confidence: 58%

“…For a magnetron discharge, the A E /A W is typical in the order of 10 −2 -10 −1 , and μ/α e is in the order of 10 −3 ; thence, the electron sheath structure may be not established in the case of a larger target area, which often occurs in the small probe tip. However, as simulated by Avino et al [50], a net negative charge density appears in front of the target centre after applying the positive pulse for ∼30 μs, leading to a potential drop correspondingly. In their work, this result can be attributed to that the electron population is repelled from the guarding line at target edge regions and drained to the target centre following the magnetic field lines.…”

Section: Double Layer Potential In Acbp-mentioning

confidence: 84%

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Ion energy distribution and non-linear ion dynamics in BP-HiPIMS and ACBP-HiPIMS discharge

Han¹,

Luo²,

Li³

et al. 2022

Plasma Sources Sci. Technol.

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Investigating the ion dynamics in the emerging bipolar pulse high power impulse magnetron sputtering (BP-HiPIMS) discharge is necessary and important for broadening its industrial applications. Recently, an optimized plasma source operating the BP-HiPIMS with an auxiliary anode and a solenoidal coil is proposed to enhance the plasma flux and energy, named as ACBP-HiPIMS (‘A’－anode, ‘C’－coil). In the present work, the temporal evolutions of the ion velocity distribution functions (IVDF) in BP-HiPIMS and ACBP-HiPIMS discharges are measured using a retarding field energy analyser (RFEA). For the BP-HiPIMS discharge, operated at various positive pulse voltages U+, the temporal evolutions of IVDFs illustrate that there are two high-energy peaks, E1 and E2, which are both lower than the applied U+. The ratio of the mean ion energy Ei,mean to the applied U+ is around 0.55－0.6 at various U+. In ACBP-HiPIMS discharge, the IVDF evolution shows three distinguishable stages which has the similar evolution trend with the floating potential Vf on the RFEA frontplate: (i) the stable stage with two high-energy peaks (E2 and E3 with energy respectively lower and higher than the applied U+ amplitude) when the floating potential Vf is close to the applied positive pulse voltage; (ii) the transition stage with low-energy populations when the Vf drops by ~20 V within ~10 μs; and (iii) the oscillation stage with alternating E2 and E3 populations and ever-present E1 population when the Vf slighly descreases unitl to the end of positive pulse. The comparison of IVDFs in BP-HiPIMS and ACBP-HiPIMS suggests that both the mean ion energy and high-energy ion flux have been effectively improved in ACBP-HiPIMS discharge. The formation of floating potential drop is explored using the Langmuir probe which may be attributed to the establishment of anode double layer structure.

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Section: Double Layer Potential In Acbp-supporting

confidence: 70%

Section: Double Layer Potential In Acbp-mentioning

confidence: 54%

Section: Double Layer Potential In Acbp-mentioning

confidence: 58%

Section: Double Layer Potential In Acbp-mentioning

confidence: 84%

See 2 more Smart Citations

Ion energy distribution and non-linear ion dynamics in BP-HiPIMS and ACBP-HiPIMS discharge

Han¹,

Luo²,

Li³

et al. 2022

Plasma Sources Sci. Technol.

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“…Thanks to this system, the niobium and copper films can be coated consecutively without venting the system in between, hence avoiding the risk of contamination due to contact with air. Before the coatings, the bakeout of the system was performed at 120 • C for 24 h. During the coatings, the equilibrium temperature reached by the system is 150 • C. All the coatings in this study were performed via the physical vapour deposition (PVD) method known as Bipolar High Power Impulse Magnetron Sputtering (Bipolar-HiPIMS) [ [11][12][13]. This technique has been shown to provide denser niobium films on copper substrate than the consolidated Direct Current Magnetron Sputtering technique, and is particularly suitable for coating surfaces at grazing incidence angles with respect to the direction of motion of the sputtered impinging ions [11,14,15].…”

Section: Coating Of Niobium and Coppermentioning

confidence: 99%

Reverse coating technique for the production of Nb thin films on copper for superconducting radio-frequency applications

Fonnesu

Baris

Amador

et al. 2022

Supercond. Sci. Technol.

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In the framework of the Future Circular Collider Study, the development of thin-film coated superconducting radio-frequency copper cavities capable of providing higher accelerating fields (10 to 20 MV/m against 5 MV/m for the Large Hadron Collider) represents a major challenge. The method investigated here for the production of seamless niobium-coated copper cavities is based on the electroforming of the copper structure around a sacrificial aluminium mandrel that is pre-coated with a niobium thin film. The first feasibility study, applied to a flat aluminium disk mandrel, is presented. Protective precautions are taken towards the functional niobium film during the production process and it is shown that this technique can deliver well performing niobium films, on a seamless copper substrate, while entirely avoiding the chemical treatments for the preparation of the substrate surface needed in the standard production processes.

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Magnetic field topology for altering ion density in bipolar sputtering

Michiels

Leonova

Snyders

et al. 2022

Applied Physics Letters

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A drastic change in the spatial ion distribution in bipolar magnetron sputtering discharge is reported upon changing the magnetic field topology. In our case, a significant increase in ion number density at certain time delays is registered when topology is changed toward the unbalanced type. A transitory torch-shaped ionization zone consequently disappears, along with the low-energy part of the ion energy distribution, due to no additional ionization in this case.

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Afterglow dynamics of plasma potential in bipolar HiPIMS discharges

Cited by 8 publications

References 28 publications

Ion energy distribution and non-linear ion dynamics in BP-HiPIMS and ACBP-HiPIMS discharge

Ion energy distribution and non-linear ion dynamics in BP-HiPIMS and ACBP-HiPIMS discharge

Reverse coating technique for the production of Nb thin films on copper for superconducting radio-frequency applications

Magnetic field topology for altering ion density in bipolar sputtering

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