Probing the electron density in HiPIMS plasmas by target inserts

Hecimovic, A.; Held, Julian; Gathen, Volker Schulz-von der; Breilmann, Wolfgang; Maszl, Christian; Keudell, Achim von

doi:10.1088/1361-6463/aa9914

Cited by 28 publications

(36 citation statements)

References 30 publications

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“…The sheath thickness in HiPIMS discharge was also calculated using Child-Langmuir law, yielding values of about 100 µm for target voltages corresponding to a power density above 250 W/cm 2 (∼ 10 A at 2" planar target). This estimate is corroborated by a benchmark experiment using an optical inspection of the sheath thickness that yields values between 50 µm and 100 µm [42,44].…”

Section: Transport At the Targetmentioning

confidence: 56%

“…At low powers typical for dcMS, spokes are Ar dominated and the plasma densities are in the order of 10 16 m −3 , the ion energy distribution function (IEDF) of metal and Ar ions arriving at the substrate are similar, comprising low energy peak of thermalised species and a tail up to 10 eV [50]. At high powers typical for HiPIMS, spokes are dominated by sputtered metal species, and the plasma densities in the spoke reach up to 8×10 19 m −3 [44]. The IEDF of metal ions consists of two main peaks at low energies (LE) as well as at high energies (HE) [51]: if the power density is increases to very high values so that the plasma becomes homogeneous again, the HE part of the metal ion IEDF does not change, but the LE peak is shifted by several eV to higher energies.…”

Section: Transport In the Vicinity Of The Substratementioning

confidence: 99%

“…• (ii) Measurement of the plasma density at the target sheath, and at 15 mm above the target surface: Measurements using circular inserts in the target showed that the plasma density increases linearly with power density, exhibiting a 25% modulation induced by the travelling spokes [44]. The average plasma density was in the range Figure 9.…”

Section: Spokes As Regions Of High Electrical Potentialmentioning

confidence: 99%

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Spokes in high power impulse magnetron sputtering plasmas

Hecimovic

Keudell²

2018

J. Phys. D: Appl. Phys.

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High power impulse magnetron sputtering (HiPIMS) is a deposition technique where a metal magnetron target is sputtered in a high density plasma to synthesize thin layers with superior properties on a substrate material. These plasmas are characterised by short pulses in the range of 50 µs to 200 µs and very high peak powers in the range of several kW/cm 2 per target area. The understanding of these dynamic plasmas is of upmost interest for the further development of this coating technique. Fast camera measurements revealed the formation of localised ionisation zones in these plasmas that propagate with a velocity of the order km/s. In the case of a circular magnetron, the movement of these ionisation zones appears like the movement of a set of spokes, which led to this common expression spoke to illustrate the pattern formation in these high density plasmas. The analysis and understanding of the spoke phenomenon is still a matter of an open debate, because the analysis and the theoretical description is hampered by the inherent complexity of these plasmas. In this paper, we review the experimental observations of the spoke phenomenon and highlight several approaches for their theoretical explanation.

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Section: Transport At the Targetmentioning

confidence: 56%

Section: Transport In the Vicinity Of The Substratementioning

confidence: 99%

Section: Spokes As Regions Of High Electrical Potentialmentioning

confidence: 99%

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Spokes in high power impulse magnetron sputtering plasmas

Hecimovic

Keudell²

2018

J. Phys. D: Appl. Phys.

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“…Probe measurements are simple to undertake, but data interpretation is difficult when a magnetic field is present 12,13 and the relative abundance of ionic species is required for calculating ion density (n i ). Previous studies have used target inserts to detect localized ionization zones (spokes) and obtain n i at the target sheath edge; 14 used outside of the magnetic trap for measurements of n i , n e , T e and the electron energy distribution function (EEDF). 8,[15][16][17] There have been fewer Langmuir probe studies within the magnetic trap 18,19 because the presence of the probe stem and current drainage to the probe tip are expected to significantly perturb the main ionization region.…”

mentioning

confidence: 99%

Comparison of Langmuir probe and laser Thomson scattering for plasma density and electron temperature measurements in HiPIMS plasma

2019

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The temporal evolution of plasma density and electron temperature in HiPIMS discharges has been measured using the Langmuir probe and laser Thomson scattering techniques. Measurements were performed (non-simultaneously) at two positions within the plasma; in the low magnetic field strength region on the discharge axis and in the high magnetic field strength region of the magnetic trap, for peak power densities of 450 Wcm −2 and 900 Wcm −2 respectively. The maximum plasma densities and temperatures were 6.9 × 10 19 m −3 and 3.7 eV in the pulse-on time, and values decayed to 4.5 × 10 17 m −3 and 0.1 eV at times up to 250 µs into the afterglow. The results indicate that although intrusive, the Langmuir probe can provide a good indication of electron properties in regions of different electron magnetization in the discharge.High power impulse magnetron sputtering (HiPIMS) is a novel ionized physical vapour deposition (IPVD) technique 1 in which high metal ionization fractions (∼ 70% in Kouznetsov et al 2 ) are obtained through the creation of a dense plasma (∼ 10 19 m −3 ). This necessitates high target power densities (0.5-10 kWcm −2 ) and these are generated using short high-voltage pulses (width ∼ 10 − 100 µs) with low duty cycle (∼ 1%) to prevent target melting. The main advantage of IPVD is that the energy and directionality of the film forming ions can be controlled by biasing the substrate, in contrast to line of sight deposition using neutrals. 3 This results in HiPIMS producing films with superior properties (e.g. denser, harder and smoother) compared to DC magnetron operation. [4][5][6] A schematic of an unbalanced planar magnetron is shown in figure 1. Electrons perform a closed E × B drift inside the last closed flux surface boundary, which confines electrons and produces a dense plasma. This magnetic trap region produces the most intense ionization in the discharge, predominately through the process of electron impact ionization. 7 There are also open flux surfaces that guide electrons which have escaped the trap (and consequently ions through ambipolar diffusion) from the target vicinity to the substrate position. A detailed understanding of the plasma dynamics inside the magnetic trap and at the substrate is required in order to optimize the deposition process. The most fundamental plasma properties for any physics investigation are electron density (n e ) and temperature (T e ).Unfortunately HiPIMS poses a difficult environment for diagnostic operation due to the high sputter flux; the relative abundance of species has a dynamic evolution; n e between pulses spans several orders of magnitude and T e at least an order of magnitude; and the plasma is spatially heterogeneous. These effects are most pronounced inside the magnetic trap. Non-intrusive diagnostics are obviously desirable and examples of such techniques applied to HiPIMS include optical emission spectroscopy 8-10 and recently THz time-domain a) Electronic mail: ryanp@liverpool.ac.uk FIG. 1. Schematic of the magnetic field from an unbalanced p...

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“…that occur due to the interaction of plasmas with other materials, and hence to focus on the fingerprints of plasma‐surface interactions . Characterization‐ and control‐related diagnostics are performed by means of Langmuir probes, laser‐based techniques, optical emission spectroscopy (OES), infrared and Fourier transform infrared absorption spectroscopy, mass spectrometry, microwave interferometry, and radio frequency diagnostics . Since low‐temperature, non‐equilibrium, and partially ionized plasmas are characterized by cold electrons (with a mean energy of bulk electrons of a few eV) dedicated methods are necessary for the qualitative/quantitative monitoring of neutral/charged atomic/molecular species and electric fields, over a wide range of pressures, electrode geometries, and gaseous mixtures .…”

Section: Challenges In Plasma Sciencementioning

confidence: 99%

White paper on the future of plasma science for optics and glass

Šimek

Černák

Kylián

et al. 2018

Plasma Processes & Polymers

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This paper reflects on the future of low-temperature plasma science in relation to the manufacturing and novel uses of glass. The text summarizes the current state of the art on the major topics discussed, such as glass processing, optics and photonics, healthcare issues, building and fenestration applications. It also identifies several challenges that are driven by applications, and which are compatible with roadmaps for their respective industries. The frontiers of plasma science are discussed, for example, in relation to the use of plasmas as an active optical element in fast-response adaptive optics systems, optical metamaterials, and the development of next-generation nanolithography. Future demand for the successful implementation of plasma-based technologies in the glass, optics, and photonic industries will depend on further progress in plasma science. Hence, some needs and recommendations concerning both fundamental and applied plasma research are summarized.

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Probing the electron density in HiPIMS plasmas by target inserts

Cited by 28 publications

References 30 publications

Spokes in high power impulse magnetron sputtering plasmas

Spokes in high power impulse magnetron sputtering plasmas

Comparison of Langmuir probe and laser Thomson scattering for plasma density and electron temperature measurements in HiPIMS plasma

White paper on the future of plasma science for optics and glass

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