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] Interaction of injected dust particles with metastable neon atoms in a radio frequency plasma. New Journal of Physics. 10, 053010 (2008).
Interaction of ion beams with dusty plasmas. Plasma Physics and Controlled Fusion. 48, B105-B113 (2006).
An interferometric force probe for beam diagnostics and the study of sputtering. EPJ Techniques and Instrumentation. 5 (2018).
Investigation of a Commercial Atmospheric Pressure Plasma Jet by a Newly Designed Calorimetric Probe. IEEE Transactions on Plasma Science. 43, 1769-1773 (2015).
Investigations of the sheath in a dual-frequency capacitively coupled rf discharge by optically trapped microparticles. Physics of Plasmas. 28, 083506 (2021).
Investigations on the energy influx at plasma processes by means of a simple thermal probe. Thin Solid Films. 377-378, 585-591 (2000).
Investigations on the energy influx at plasma surface processes. Acta Phys. Slovaca. 50, 439-459 (2000).
Ion Molecule and Dust Particle Formation in Ar/CH4, Ar/C2H2 and Ar/C3H6 Radio-frequency Plasmas. Contributions to Plasma Physics. 45, 378-384 (2005).
Langmuir probe measurements in nanodust containing argon-acetylene plasmas. Vacuum. 166, 15-25 (2019).
Laser schlieren deflectometry for temperature analysis of filamentary non-thermal atmospheric pressure plasma. Review of Scientific Instruments. 83, 103506 (2012).
Low-temperature plasmas in carbon nanostructure synthesis. Journal of Vacuum Science & Technology B: Microelectronics and Nanometer Structures. 31, 050801 (2013).
Machbarkeitsuntersuchungen zu einem elektrostatischen Mikropartikeltriebwerk. Hannover: Technische Informationsbibliothek; 2008.
Mass Spectrometric Investigations of Nano-Size Cluster Ions Produced by High Pressure Magnetron Sputtering. Contributions to Plasma Physics. 52, 881-889 (2012).
Mass Spectrometric Investigations on Aluminum Isopropoxide Containing Plasmas. Plasma Processes and Polymers. 9, 904-910 (2012).
Measurement and modeling of neutral, radical, and ion densities in H2-N2-Ar plasmas. Journal of Applied Physics. 117, 083303 (2015).
Measurement and simulation of forces generated when a surface is sputtered. Physics of Plasmas. 24, 093501 (2017).
Measurement and simulation of the momentum transferred to asurface by deposition of sputtered atoms. The European Physical Journal D. 70 (2016).
Measurement of CH4-concentration in HMDSO-containing process plasmas by quantum cascade laser absorption spectroscopy. Vacuum. 85, 482-485 (2010).
On the measurement of energy fluxes in plasmas using a calorimetric probe and a thermopile sensor. Journal of Physics D: Applied Physics. 43, 465201 (2010).
Measurement of forces exerted by low-temperature plasmas on a plane surface. Plasma Sources Science and Technology. 26, 055011 (2017).
Measurement of plasma-surface energy fluxes in an argon rf-discharge by means of calorimetric probes and fluorescent microparticles. Physics of Plasmas. 17, 113707 (2010).
Measurement of the electric charge on particulates forming Coulomb crystals in the sheath of a radiofrequency plasma. Plasma Sources Science and Technology. 4, 450-458 (1995).
Measurement of the force exerted on the surface of an object immersed in a plasma. The European Physical Journal D. 69 (2015).
Measurement of the force on microparticles in a beam of energetic ions and neutral atoms. Physics of Plasmas. 17, 103702 (2010).
Measurement of the Force on Microparticles in an Energetic Ion Beam. IEEE Transactions on Plasma Science. 38, 774-780 (2010).
Measuring the temperature of microparticles in plasmas. Review of Scientific Instruments. 79, 093508 (2008).
Messung von Kräften auf Oberflächen durch Partikelstrahlen und Plasmen als Diagnostik für Impulsflüsse, Sputtern und Plasma-Wand-Wechselwirkungen. Kiel: Christian-Albrechts-Universität zu Kiel, Institut für Experimentelle und Angewandte Physik; 2018.
Metal/polymer nanocomposite thin films prepared by plasma polymerization and high pressure magnetron sputtering. Surface and Coatings Technology. 205, S38-S41 (2011).
The method of conventional calorimetric probes — A short review and application for the characterization of nanocluster sources. Surface and Coatings Technology. 205, S388-S392 (2011).
Microcalorimetry of dust particles in a radio-frequency plasma. Journal of Applied Physics. 88, 1747 (2000).
Micro-disperse particles as probes for plasma surface interaction. Thin Solid Films. 377-378, 530-536 (2000).
Micro-Disperse Particles in Plasmas: From Disturbing Side Effects to New Applications. Contributions to Plasma Physics. 41, 598-609 (2001).
Micro-Particles as Electrostatic Probes for Plasma Sheath Diagnostics. Plasma Processes and Polymers. 6, S620-S625 (2009).
Microparticles as Plasma Diagnostic Tools. Contributions to Plasma Physics. 51, 218-227 (2011).
Microparticles in a Collisional Rf Plasma Sheath under Hypergravity Conditions as Probes for the Electric Field Strength and the Particle Charge. Physical Review Letters. 106 (2011).
Microparticles in plasmas as diagnostic tools and substrates. Faraday Discussions. 137, 157 (2007).
Microplasmas: scientific challenges & technological opportunities. The European Physical Journal D. 60, 437-439 (2010).
Modeling of argon-acetylene dusty plasma. Plasma Physics and Controlled Fusion. 61, 014014 (2019).
Modeling of parasitic plasma under the divertor roof baffle. Journal of Nuclear Materials. 337-339, 237-240 (2005).
Modification of a metal nanoparticle beam by a hollow electrode discharge. Journal of Vacuum Science & Technology A: Vacuum, Surfaces, and Films. 34, 021301 (2016).
Modification of polyethylene powder with an organic precursor in a spiral conveyor by hollow cathode glow discharge. The European Physical Journal D. 58, 305-310 (2010).
On the modification of powder particles in a process plasma. AIP proceedings "Dusty plasmas in the new millenium". 649 (2002).
Nanoparticle forming reactive plasmas: A multidiagnostic approach. The European Physical Journal D. 72 (2018).
Non-Electrostatic Diagnostics for Ion Beams. Contributions to Plasma Physics. 52, 584-592 (2012).
Non-electrostatic diagnostics for ion beams and sputter effects. Plasma Physics and Controlled Fusion. 54, 124005 (2012).
Optical diagnostics of dusty plasmas during nanoparticle growth. Plasma Physics and Controlled Fusion. 59, 014034 (2017).
An optical trapping system for particle probes in plasma diagnostics. Review of Scientific Instruments. 89, 103505 (2018).
Particle formation during deposition of SiOx nanostructured thin films by atmospheric pressure plasma jet. Japanese Journal of Applied Physics. 59, SHHE06 (2020).
Particle Trapping in Corners of Horizontal Electrodes and Vertical Walls. In: DUSTY∕COMPLEX PLASMAS: BASIC AND INTERDISCIPLINARY RESEARCH: Sixth International Conference on the Physics of Dusty Plasmas. Garmisch-Partenkirchen (Germany): AIP; 2011.
Particle-in-Cell Simulation of a Down-Scaled HEMP Thruster. Trans. JSASS Aerospace Tech. Japan. 14, 235-242 (2016).
Particles as probes for complex plasmas in front of biased surfaces. New Journal of Physics. 11, 013041 (2009).
Phänomene in Gasentladungen. Galvanotechnik. 103, 1080-1088 (2012).
Phänomene in Gasentladungen: Stehende Schichten. Galvanotechnik. 101, 866-871 (2010).
Plasma and ion beam characterization by non-conventional methods. Surface and Coatings Technology. 200, 809-813 (2005).
Plasma based formation and deposition of metal and metal oxide nanoparticles using a gas aggregation source. The European Physical Journal D. 72 (2018).
Plasma Bubble in an RF Reactor. IEEE Transactions on Plasma Science. 36, 1370-1371 (2008).
Plasma characterization in reactive sputtering processes of Ti in Ar/O2 mixtures operated in metal, transition and poisoned modes: a comparison between direct current and high-power impulse magnetron discharges. The European Physical Journal D. 71, 245 (2017).
Plasma characterization tools and application to reactive sputtering of Al-doped ZnO thin films. Glass coatings. Products, technology, applications. 1, 46-50 (2006).
Plasma Chemical Study of a RF Discharge Containing Aluminum Tri-Isopropoxide Using MIR Absorption Spectroscopy Based on External-Cavity Quantum Cascade Lasers. Contributions to Plasma Physics. 52, 864-871 (2012).
On the Plasma Chemistry of an RF Discharge Containing Aluminium Tri-Isopropoxide Studied by FTIR Spectroscopy. Contributions to Plasma Physics. 54, 170-186 (2014).
Plasma engineering of silicon quantum dots and their properties through energy deposition and chemistry. Phys. Chem. Chem. Phys.. 18, 25837-25851 (2016).
On the plasma permeability of highly porous ceramic framework materials using polymers as marker materials. Plasma Processes and Polymers (2022).
Plasma properties as function of time in Ar/C2H2 dust-forming plasma. Journal of Physics D: Applied Physics. 53, 135203 (2020).
Plasma response to nanoparticle growth. In: INTERNATIONAL CONFERENCE FOR SCIENCE EDUCATORS AND TEACHERS (ISET) 2017: Proceedings of the 5th International Conference for Science Educators and Teachers (ISET) 2017. Phuket, Thailand: Author(s); 2018.
Plasma Sheath Structures in Complex Electrode Geometries. Contributions to Plasma Physics. 52, 827-835 (2012).
Plasma Treatment of Polyethylene Powder Particles in a Hollow Cathode Glow Discharge. Plasma Processes and Polymers. 6, S392-S396 (2009).
Plasma under control: advanced solutions and perspectives for plasma flux management in material treatment and nanosynthesis. Applied Physics Reviews. 4, 041302 (2017).
Plasmatechnik 4.0: Stand der Technik, Entwicklungen und Erwartungen. Vakuum in Forschung und Praxis. 30, 34-39 (2018).
Plasma–powder interaction: trends in applications and diagnostics. International Journal of Mass Spectrometry. 223-224, 313-325 (2003).
Power outflux from the plasma: an important parameter in surface processing. Plasma Physics and Controlled Fusion. 46, B167-B177 (2004).
Pretreatment of cutting tools by plasma electrolytic polishing (PEP) for enhanced adhesion of hard coatings. Surface and Coatings Technology. 405, 126504 (2021).
Probing the Plasma Sheath by the Continuous Mass Loss of Microparticles. IEEE Transactions on Plasma Science. 41, 764-768 (2013).
Real-time monitoring of nucleation-growth cycle of carbon nanoparticles in acetylene plasmas. Journal of Applied Physics. 109, 123305 (2011).
Reinigung und Oberflächenbehandlung von Daguerreotypien mittels physikalischer Plasmaverfahren. Restauratorenblätter. 37 (2020).
Resonance cones in a dusty magnetized plasma. Physics of Plasmas. 10, 4627 (2003).
On An RF Discharge With An Adaptive Electrode For Powder Treatment. In: NEW VISTAS IN DUSTY PLASMAS: Fourth International Conference on the Physics of Dusty PlasmasAIP Conference Proceedings. Orleans (France): AIP; 2005.
Rotating dust ring in an RF discharge coupled with a dc-magnetron sputter source. Experiment and simulation. Journal of Physics D: Applied Physics. 37, 2703-2708 (2004).
Shaping thin film growth and microstructure pathways via plasma and deposition energy: a detailed theoretical, computational and experimental analysis. Phys. Chem. Chem. Phys.. 19, 5591-5610 (2017).
Simulations on the influence of the spatial distribution of source electrons on the plasma in a cusped-field thruster. The European Physical Journal D. 69 (2015).
Spatially resolved thermal probe measurement for the investigation of the energy influx in an rf-plasma. Vacuum. 83, 768-772 (2008).
Spatiotemporal sampling of growing nanoparticles in an acetylene plasma. Journal of Applied Physics. 127, 173301 (2020).
Staubige Plasmen: Mikropartikel als Sonden im Plasma. PlasmaNews des TechPortal VDI/Bmbf (2007).
Staubige Plasmen: Von störenden Nebeneffekten zu neuen Anwendungen. PlasmaNews des TechPortal VDI/Bmbf (2007).
Surface loss probability of atomic hydrogen for different electrode cover materials investigated in H2-Ar low-pressure plasmas. Journal of Applied Physics. 116, 013302 (2014).
Surface modification of highly porous 3D networks via atmospheric plasma treatment. Contributions to Plasma Physics (2018).
Surface Processes of Dust Particles in Low Pressure Plasmas. Physica Scripta. T89, 168 (2001).
Surface States and the Charge of a Dust Particle in a Plasma. Physical Review Letters. 101 (2008).
On the synthesis and processing of nanoparticles by plasmas. Problems of Atomic Science and Technology (PAST). 6 (2016).
SYPO Special Issue. Vacuum. 71, 347 (2003).
The temperature of microparticles in a low-pressure discharge as a plasma diagnostic tool. In: DUSTY∕COMPLEX PLASMAS: BASIC AND INTERDISCIPLINARY RESEARCH: Sixth International Conference on the Physics of Dusty Plasmas. Garmisch-Partenkirchen (Germany): AIP; 2011.
Temperature of Particulates in Low-Pressure rf-Plasmas in Ar, Ar/H2 and Ar/N2 Mixtures. Contributions to Plasma Physics. 50, 954-961 (2010).
Thin film deposition on powder surfaces using atmospheric pressure discharge. In: NEW VISTAS IN DUSTY PLASMAS: Fourth International Conference on the Physics of Dusty PlasmasAIP Conference Proceedings. Orleans (France): AIP; 2005.
Towards a Microscopic Theory of Particle Charging. Contributions to Plasma Physics. 49, 303-315 (2009).
Towards a Particle Based Simulation of Complex Plasma Driven Nanocomposite Formation. Contributions to Plasma Physics. 52, 890-898 (2012).
Transient calorimetric diagnostics for plasma processing. The European Physical Journal D. 67 (2013).
Tunable ion flux density and its impact on AlN thin films deposited in a confocal DC magnetron sputtering system. Surface and Coatings Technology. 348, 159-167 (2018).
Understanding the energy balance of a surface barrier discharge for various molecular gases by a multi-diagnostic approach. Journal of Applied Physics. 129, 053308 (2021).
On the use of optically trapped dust particles as micro-probes in process plasmas. Problems of Atomic Science and Technology (PAST) . 1, 164-167 (2013).
The Use of Passive Thermal Probes for the Determination of Energy Fluxes in Atmospheric Pressure Plasmas. IEEE Transactions on Plasma Science. 49, 3325-3335 (2021).
Versatile particle collection concept for correlation of particle growth and discharge parameters in dusty plasmas. Journal of Physics D: Applied Physics. 48, 055203 (2015).