Detailseite
Non-linear femtosecond optics and waveguiding in single zincoxide nanowires
Antragsteller
Professor Dr. Tobias Voß
Fachliche Zuordnung
Experimentelle Physik der kondensierten Materie
Förderung
Förderung von 2006 bis 2008
Projektkennung
Deutsche Forschungsgemeinschaft (DFG) - Projektnummer 25023998
Erstellungsjahr
2007
Zusammenfassung der Projektergebnisse
Keine Zusammenfassung vorhanden
Projektbezogene Publikationen (Auswahl)
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13th International Conference on II-VI Compounds, Jeju (Korea), 2007. Femtosecond excitation of bulk ZnO: material modification and ultrafast dynamics
T. Shih, T. Voss, M. T. Winkler, and E. Mazur
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13th International Conference on II-VI Compounds, Jeju (Korea), 2007. Measuring the transmission losses of a single ZnO nanowire
T. Voss, G. T. Svacha, and E. Mazur
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397. WE-Heraeus-Seminar„Semiconducting Nanowires: Physics, Materials and Devices" (2007). ZnO nanowires: waveguide modes, coupling, and non-linear optics
T. Voss, G. T. Svacha, and E. Mazur
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Condensed Matter and Applied Physics Seminar, Harvard School of Engineering and Applied Sciences: Top-down and bottom-up: nano-optics with zinc oxide and silica nanowires. Cambridge, MA, USA (March 2007)
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Hanse Wissenschaftskolleg, Workshop From Materials to Functional Materials: Top-down and bottom-up: nano-optics with zinc oxide and silica nanowires. Delmenhorst, Germany, (July 2007)
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Photonics West 2007, San Jose (USA). Efficient coupling between guided optical modes in ZnO nanowire-waveguides and tapered silica fibers
T. Voss, G. T. Svacha, and E. Mazur
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Seminar at the LCMTR, Institut des Sciences Chimiques Seine Amont, CNRS, Paris (France): Top-down and bottom-up: nano-optics with zinc oxide and silica nanowires. Paris, France, (October 2007)
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Seminar at the University of Southern California at Los Angeles, Department of Physics and Astronomy: Surface effects and waveguiding in single ZnO nanowires. Los Angeles, CA, USA (February 2007)
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Photonics West 2008, San Jose (USA). Femtosecond excitation of bulk ZnO: material modification and ultrafast dynamics
T. Voss, T. Shih, and E. Mazur