Publications

Kitsukis A.. Untersuchung der Emission von Kapillaren beim Laserstrahlschweißen mittels Raytracing. IFSW20-08Okt 2020. [PUMA: Simulation Laser Schweißen from:julianholland Weber,R. Makrobearbeitung Sawannia,M.]

Petar A. Atanasov, Nikolay N. Nedialkov, S.E. Imamova, Andreas Ruf, Helmut Hügel, Friedrich Dausinger, and Peter Berger. Laser ablation of Ni by ultrashort pulses: molecular dynamics simulation. Applied Surface Science, (186):369-373, 2002. [PUMA: Simulation Laser Modelling Ablation from:peterberger]

Markus Beck, Peter Berger, and Helmut Hügel. The effect of plasma formation on beam focusing in deep penetration welding with CO2 lasers. Journal of Physics D: Applied Physics, (28):2430, 1995. [PUMA: Welding Simulation Laser Modelling from:peterberger]

Markus Beck, Friedrich Dausinger, and Helmut Hügel. Modell zur Beschreibung der Energieeinkopplung von CO2-Laserstrahlung beim Tiefschweißen. In Wilhelm Waidelich (Eds.), Proceedings of the 9th International Congress LASER 89, 550, Springer, Berlin, 1990. [PUMA: Welding Simulation Laser Modeling from:peterberger]

Markus Beck, Friedrich Dausinger, and Helmut Hügel. Studie zur Energieeinkopplung beim Tiefschweißen mit Laserstrahlung. Laser und Optoelektronik, (21)3:80 - 84, AT-Fachverlag, Stuttgart, 1989. [PUMA: Welding Simulation Laser Modelling from:peterberger]

Markus Beck, Markus Kern, Peter Berger, and Helmut Hügel. Einfluß der Plasmawolke auf Einkopplung und Prozeßstabilität beim Lasertiefschweißen mit CO2-Lasern. Laser und Optoelektronik, (28)4:72-78, 1996. [PUMA: Welding Simulation Laser Modelling from:peterberger]

Peter Berger, Helmut Hügel, and Thomas Graf. Understanding Pore Formation in Laser Beam Welding. Phsics Procedia, (12, Part A):0, Elsevier Ltd., Amsterdam, 2011. [PUMA: LaserMatterInteraction Diagnostics Welding Simulation Laser MacroMaterialProcessing Modeling from:peterberger]

Peter Berger, Helmut Hügel, and Thomas Graf. Understanding Pore Formation in Laser Beam Welding. Phsics Procedia, (12, Part A)Elsevier Ltd., Amsterdam, 2011. [PUMA: LaserMatterInteraction Diagnostics Welding Simulation Laser MacroMaterialProcessing Modeling from:peterberger]

Peter Berger, Helmut Hügel, Axel Heß, Rudolf Weber, and Thomas Graf. Understanding of Humping Based on Conservation of Volume Flow. Phsics Procedia, (12, Part A)Elsevier Ltd., Amsterdam, 2011. [PUMA: LaserMatterInteraction Diagnostics Welding Simulation Laser MacroMaterialProcessing Modeling from:peterberger]

Detlef Breitling, Henrik Schittenhelm, Peter Berger, Friedrich Dausinger, and Helmut Hügel. Shadowgraphic and interferometric investigations on Nd:YAG laser-induced vapor/plasma plumes for different processing wavelengths. Applied Physics, A 69 Suppl:505, 1999. [PUMA: LaserMatterInteraction Diagnostics Simulation Laser Modelling from:peterberger]

Gert Callies, Henrik Schittenhelm, Peter Berger, and Helmut Hügel. Modeling of cluster generation in excimer laser induced plasma/vapour plumes. (EUROMECH Colloqium 363, Mechanics of Laser Ablation, 23.-26. June 1997). Thermo, (5)2:235, 1998. [PUMA: Simulation Laser Modelling Ablation from:peterberger]

Gert Callies, Henrik Schittenhelm, Peter Berger, and Helmut Hügel. Modeling of the expansion of laser-evapourated matter in argon, helium and nitrogen and the condensation of clusters. Applied Surface Science, (127):131, 1998. [PUMA: Simulation Laser Modelling Ablation from:peterberger]

Karsten Contag, Martin Karszewski, Carsten Stewen, Adolf Giesen, and Helmut Hügel. Theoretical modelling and experimental investigations of the diode-pumped thin disk Yb:YAG laser. Quantum Electronics, (29)8:697, 1999. [PUMA: Simulation Laser Diodepumped Modelling from:peterberger]

M. Danke. Schweißen mit Beam-Combining ; -Simulation und Experiment. IFSW92-28July 1992. [PUMA: Beck,Markus Welding Simulation Laser from:florianfetzer ProcessDevelopment Diplomarbeit]

Tom Dietrich, Christoph Röcker, Thomas Graf, and Marwan Abdou Ahmed. Modelling of natural convection in thin-disk lasers. Applied Physics B, (126)3:47, Springer, March 2020. [PUMA: myown Peer Simulation Laser from:christophrcker ThindiskLaser] URL

Florian Fetzer, Peter Stritt, Peter Berger, Rudolf Weber, and Thomas Graf. Fast numerical method to predict the depth of laser welding. Journal of Laser Applications, (29)2:022012, 2017. [PUMA: myown Welding Peer Simulation Laser Modelling from:peterberger]

Christian Freitag, Rudolf Weber, and Thomas Graf. Polarization dependence of laser interaction with carbon fibers and CFRP. Optics Express, (22)2:1474-1479, 2014. [PUMA: LaserMatterInteraction myown Simulation Laser Modelling from:peterberger]

Daniel Johannes Förster, Stefan Scharring, Johannes Roth, and Hans-Albert Eckel. Molecular Dynamics Simulations of Laser Induced Ablation for Micro Propulsion. High Performance Computing in Science and Engineering ‘14, 139--152, Springer, 2015. [PUMA: ultrafast myown from:djfoerster ablation dynamics laser molecular simulation]

Karin Heller. Analytische Temperaturfeldbeschreibung beim Laserstrahlschweißen für thermographische Prozessbeobachtung. In Thomas Graf (Eds.), Laser in der Materialbearbeitung - Forschungsberichte des IFSW, 130, Herbert Utz Verlag, München, 2017. [PUMA: Welding Simulation Laser Modeling from:peterberger]

Karin Heller, Steffen Kessler, Friedhelm Dorsch, Peter Berger, and Thomas Graf. Analytical description of the surface temperature for the characterization of laser welding processes. International Journal of Heat and Mass Transfer, (106):958-969, 2017. [PUMA: myown Welding Simulation peer Laser Modelling from:peterberger]