Time-resolved imaging of sputtered particles in multi-pulse HiPIMS discharge

HNILICA, Jaroslav, Peter KLEIN, Pavel SOUČEK, Petr VAŠINA, Rony SNYDERS and Nikolay BRITUN. Time-resolved imaging of sputtered particles in multi-pulse HiPIMS discharge. In PLATHINIUM Plasma Thin Film International Union Meeting. 2019.

Basic information

• Original name: Time-resolved imaging of sputtered particles in multi-pulse HiPIMS discharge
• Authors: HNILICA, Jaroslav (203 Czech Republic, belonging to the institution), Peter KLEIN (703 Slovakia, belonging to the institution), Pavel SOUČEK (203 Czech Republic, belonging to the institution), Petr VAŠINA (203 Czech Republic), Rony SNYDERS and Nikolay BRITUN.
• Edition: PLATHINIUM Plasma Thin Film International Union Meeting, 2019.

Other information

• Original language: English
• Type of outcome: Conference abstract
• Field of Study: 10305 Fluids and plasma physics
• Country of publisher: France
• Confidentiality degree: is not subject to a state or trade secret
• RIV identification code: RIV/00216224:14310/19:00112734
• Organization unit: Faculty of Science
• Keywords in English: magnetron sputtering; HiPIMS; multi-pulse; AAS; LIF
• Tags: International impact

Abstract

Ten years ago, an alternative high-power impulse magnetron sputtering (HiPIMS) deposition technique known as modulated pulsed power (MPP) magnetron sputtering has been introduced by Chistyakov et al. In MPP a long pulse is divided into many sub-pulses, which vary from few to tens of microseconds. Operating the HiPIMS in similar mode is called multi-pulse HiPIMS (m-HiPIMS). In the pulse sequence a large quantity of thermalized sputtered atoms, which were not ionized during the preceding pulse, are available to be ionized during the subsequent pulse. It leads to significant enhancement of total ion flux to the substrate and deposition rate. Direct imaging of sputtered particles above the magnetron target is a straightforward way to obtain information about the number density of neutrals and ions, degree of ionization or time of ion arrival to the virtual substrate. This work is focused on the dynamics of the ground state Ti atoms and singly ionized ions. It is achieved by their visualization using laser-induced fluorescence (LIF) imaging technique [4] combined with atomic absorption spectroscopy. In our study, the effects of the pulse duration, delay between the pulses and their number are examined. The effect of pulse number for better ionization control in the m-HiPIMS case is demonstrated. This phenomenon is related to the synchronization with both the wave of ions propagating from the cathode and following m-HiPIMS pulse (so-called ‘ion pumping’). Moreover, the influence of multi-pulse on the structure of the metallic titanium coating is studied. The results of this study can already be utilized to control the ionization degree in real processes involving HiPIMS discharges.

Links

• LO1411, research and development project: Name: Rozvoj centra pro nízkonákladové plazmové a nanotechnologické povrchové úpravy (Acronym: CEPLANT plus)

Investor: Ministry of Education, Youth and Sports of the CR