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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.
An advanced electric propulsion diagnostic (AEPD) platform for in-situ characterization of electric propulsion thrusters and ion beam sources. The European Physical Journal D. 70 (2016).
An advanced electric propulsion diagnostic (AEPD) platform for in-situ characterization of electric propulsion thrusters and ion beam sources. The European Physical Journal D. 70 (2016).
An advanced electric propulsion diagnostic (AEPD) platform for in-situ characterization of electric propulsion thrusters and ion beam sources. The European Physical Journal D. 70 (2016).
An advanced electric propulsion diagnostic (AEPD) platform for in-situ characterization of electric propulsion thrusters and ion beam sources. The European Physical Journal D. 70 (2016).
Angularly and Spatially Resolved Measurements of the Energy Flux in an RF Plasma Using a Thermal Probe. Plasma Processes and Polymers. 6, S626-S630 (2009).
Behavior of a porous particle in a radiofrequency plasma under pulsed argon ion beam bombardment. New Journal of Physics. 12, 033036 (2010).
Behavior of a porous particle in a radiofrequency plasma under pulsed argon ion beam bombardment. New Journal of Physics. 12, 033036 (2010).
Broad Beam Ion Sources for Electrostatic Space Propulsion and Surface Modification Processes: From Roots to Present Applications. Contributions to Plasma Physics. 47, 487-497 (2007).
Calorimetric investigations in a gas aggregation source. Journal of Applied Physics. 124, 1-10 (2018).
A calorimetric probe for plasma diagnostics. Review of Scientific Instruments. 81, 023504 (2010).
Characterization of a broad ion beam source by determination of the energy flux. Surface and Coatings Technology. 174-175, 918-921 (2003).
Characterization of a radio frequency hollow electrode discharge at low gas pressures. Physics of Plasmas. 22, 083513 (2015).
Characterization of the energy flux toward the substrate during magnetron sputter deposition of ZnO thin films. Plasma Sources Science and Technology. 22, 025019 (2013).
Comparison of calorimetric plasma diagnostics in a plasma downstream reactor. Journal of Physics D: Applied Physics. 44, 095201 (2011).
Controlled synthesis of germanium nanoparticles by nonthermal plasmas. Applied Physics Letters. 108, 093105 (2016).
Conventional and non-conventional diagnostics of a stable atmospheric pressure DC normal glow microplasma discharge intended for in situ TEM studies. Plasma Sources Science and Technology. 31, 035013 (2022).
Correlation between properties of direct current magnetron sputtered thin niobium nitride films and plasma parameters. Thin Solid Films. 742, 139046 (2021).
Correlation between sputter deposition parameters and I-V-characteristics in double-barrier memristive devices. Journal of Vacuum Science & Technology B. 37, 061203 (2019).
Correlation between sputter deposition parameters and I-V-characteristics in double-barrier memristive devices. Journal of Vacuum Science & Technology B. 37, 061203 (2019).
Deposition of Zn-containing films using atmospheric pressure plasma jet. Open Chemistry. 13 (2014).
On the determination of energy fluxes at plasma–surface processes. Applied Physics A Materials Science & Processing. 72, 531-540 (2001).
On the determination of energy fluxes at plasma–surface processes. Applied Physics A Materials Science & Processing. 72, 531-540 (2001).
Determination of Plasma Parameters during Deposition of ZnO Films by Ceramic and Metallic Targets and Correlation with Film Properties. Plasma Processes and Polymers. 4, S527-S530 (2007).
Determination of sheath parameters by test particles upon local electrode bias and plasma switching. The European Physical Journal D. 63, 431-440 (2011).
Diagnostics of process plasma used for the production of memristive devices. Journal of Physics: Conference Series. 1492, 012002 (2020).
Die Bestimmung von Energieflüssen bei Plasma-Oberflächen-Prozessen. Galvanotechnik. 96, 2996-3007 (2005).
Discharge power dependence of carbon dust flux in a divertor simulator. Journal of Nuclear Materials. 438, S788-S791 (2013).
Discharge power dependence of carbon dust flux in a divertor simulator. Journal of Nuclear Materials. 438, S788-S791 (2013).
Discharge power dependence of carbon dust flux in a divertor simulator. Journal of Nuclear Materials. 438, S788-S791 (2013).
Dust particles in collisionless plasma sheath with arbitrary electron energy distribution function. The European Physical Journal D. 54, 219-224 (2009).
Effects of Hydrogen Dilution on ZnO Thin Films Fabricated via Nitrogen-Mediated Crystallization. Japanese Journal of Applied Physics. 52, 01AC08 (2013).
Effects of Hydrogen Dilution on ZnO Thin Films Fabricated via Nitrogen-Mediated Crystallization. Japanese Journal of Applied Physics. 52, 01AC08 (2013).
Effects of Hydrogen Dilution on ZnO Thin Films Fabricated via Nitrogen-Mediated Crystallization. Japanese Journal of Applied Physics. 52, 01AC08 (2013).
Einsatz von Atmosphärendruckplasmen für Anwendungen in der Druckindustrie. Galvanotechnik. 108, 1658-1665 (2017).
Electron stochastic heating in a capacitively coupled low-pressure argon rf-discharge. Plasma Sources Science and Technology. 18, 025026 (2009).
Electron stochastic heating in a capacitively coupled low-pressure argon rf-discharge. Plasma Sources Science and Technology. 18, 025026 (2009).
The energy balance at substrate surfaces during plasma processing. Vacuum. 63, 385-431 (2001).
Energy flux characterization of atmospheric pressure plasma spray torches with passive thermal probes. Journal of Thermal Spray Technology (2022).
Energy flux measurements in high power impulse magnetron sputtering. Journal of Physics D: Applied Physics. 42, 185202 (2009).
Energy influx from an rf plasma to a substrate during plasma processing. Journal of Applied Physics. 87, 3637 (2000).
Energy influx from an rf plasma to a substrate during plasma processing. Journal of Applied Physics. 87, 3637 (2000).
Energy-dependent film growth of Cu and NiTi from a tilted DC magnetron sputtering source determined by calorimetric probe analysis. Surface and Coatings Technology. 450, 129000 (2022).
Examples for application and diagnostics in plasma–powder interaction. New Journal of Physics. 5, 93 (2003).
An experiment for the investigation of forces on microparticles in ion beams. Review of Scientific Instruments. 81, 013503 (2010).
Fabrication of ZnO Nanobrushes by H2–C2H2 Plasma Etching for H2 Sensing Applications. ACS Applied Materials & Interfaces. 13, 61758 (2021).
Fabrication of ZnO Nanobrushes by H2–C2H2 Plasma Etching for H2 Sensing Applications. ACS Applied Materials & Interfaces. 13, 61758 (2021).
Force probes for development and testing of different electric propulsion systems. EPJ Techniques and Instrumentation. 9 (2022).
Fourier Analysis of Particle Motion in a Radio Frequency Plasma Under Pulsed Argon Ion Beam Bombardment. IEEE Transactions on Plasma Science. 38, 810-813 (2010).
Gezielte Manipulation von Mikropartikeln in einem Plasma. Manipulation of micro-disperse particles in a process plasma. Vakuum in Forschung und Praxis. 17, 259-261 (2005).
An in-flight plasma diagnostic package for spacecraft with electric propulsion. EPJ Techniques and Instrumentation. 8 (2021).
An in-flight plasma diagnostic package for spacecraft with electric propulsion. EPJ Techniques and Instrumentation. 8 (2021).
An in-flight plasma diagnostic package for spacecraft with electric propulsion. EPJ Techniques and Instrumentation. 8 (2021).
An in-flight plasma diagnostic package for spacecraft with electric propulsion. EPJ Techniques and Instrumentation. 8 (2021).
Influence of a liquid surface on the NO x production of a cold atmospheric pressure plasma jet. Journal of Physics D: Applied Physics. 51, 474002 (2018).
Influence of nanoparticle formation on discharge properties in argon-acetylene capacitively coupled radio frequency plasmas. Applied Physics Letters. 108, 063108 (2016).
In-situ laser light scattering for temporally and locally resolved studies on nanoparticle trapping in a gas aggregation source. Particle & Particle Systems Characterization. 2200112 (2022).
Instrument for spatially resolved simultaneous measurements of forces and currents in particle beams. Review of Scientific Instruments. 86, 015107 (2015).
An interferometric force probe for beam diagnostics and the study of sputtering. EPJ Techniques and Instrumentation. 5 (2018).
Investigations of the sheath in a dual-frequency capacitively coupled rf discharge by optically trapped microparticles. Physics of Plasmas. 28, 083506 (2021).
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 surface processes. Acta Phys. Slovaca. 50, 439-459 (2000).
Investigations on the energy influx at plasma surface processes. Acta Phys. Slovaca. 50, 439-459 (2000).
Laser schlieren deflectometry for temperature analysis of filamentary non-thermal atmospheric pressure plasma. Review of Scientific Instruments. 83, 103506 (2012).
Laser schlieren deflectometry for temperature analysis of filamentary non-thermal atmospheric pressure plasma. Review of Scientific Instruments. 83, 103506 (2012).
Mass Spectrometric Investigations of Nano-Size Cluster Ions Produced by High Pressure Magnetron Sputtering. Contributions to Plasma Physics. 52, 881-889 (2012).
Measurement and modeling of neutral, radical, and ion densities in H2-N2-Ar plasmas. Journal of Applied Physics. 117, 083303 (2015).
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).
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).
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 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).
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-Disperse Particles in Plasmas: From Disturbing Side Effects to New Applications. Contributions to Plasma Physics. 41, 598-609 (2001).
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).
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).
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. Contributions to Plasma Physics. 52, 584-592 (2012).
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).
An optical trapping system for particle probes in plasma diagnostics. Review of Scientific Instruments. 89, 103505 (2018).
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).
Particles as probes for complex plasmas in front of biased surfaces. New Journal of Physics. 11, 013041 (2009).
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 tools and application to reactive sputtering of Al-doped ZnO thin films. Glass coatings. Products, technology, applications. 1, 46-50 (2006).
Plasma characterization tools and application to reactive sputtering of Al-doped ZnO thin films. Glass coatings. Products, technology, applications. 1, 46-50 (2006).
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).