As part of his research on Laser beams, studies on Laser beam quality and Beam divergence are part of the effort. His Laser beam quality study frequently intersects with other fields, such as Laser beams. Optoelectronics connects with themes related to Tunable laser in his study. Optics is closely attributed to Beam (structure) in his research. Beam (structure) is closely attributed to Optics in his study. In his study, G. Erbert carries out multidisciplinary Laser and Fiber laser research. His research on Fiber laser frequently connects to adjacent areas such as Optoelectronics. His Diode study frequently draws connections between related disciplines such as Semiconductor laser theory. He regularly links together related areas like Quantum mechanics in his Semiconductor laser theory studies.
His Diode research also covers Semiconductor laser theory and Laser diode studies. Laser diode is frequently linked to Diode in his study. His research on Optics often connects related areas such as Beam (structure). His work in Beam (structure) is not limited to one particular discipline; it also encompasses Optics. In his study, he carries out multidisciplinary Optoelectronics and Gallium arsenide research. G. Erbert undertakes interdisciplinary study in the fields of Laser and Wavelength through his works. Wavelength is closely attributed to Optoelectronics in his research. His research on Quantum mechanics often connects related topics like Power (physics). His research on Power (physics) often connects related areas such as Quantum mechanics.
His Optics study frequently links to related topics such as Absorption (acoustics). His work on Optics expands to the thematically related Absorption (acoustics). His study on Laser is mostly dedicated to connecting different topics, such as Optical power. Many of his studies on Optoelectronics involve topics that are commonly interrelated, such as Waveguide. He integrates Waveguide with Laser in his study. His Thermodynamics study frequently draws connections to other fields, such as Power (physics). His Quantum mechanics research extends to Power (physics), which is thematically connected. His Quantum mechanics study frequently draws connections between adjacent fields such as Realisation. G. Erbert brings together Wavelength and Brillouin scattering to produce work in his papers.
His Optics study frequently draws parallels with other fields, such as Absorption (acoustics). His study brings together the fields of Optics and Absorption (acoustics). In his work, G. Erbert performs multidisciplinary research in Inertial confinement fusion and National Ignition Facility. His multidisciplinary approach integrates National Ignition Facility and Hohlraum in his work. G. Erbert merges Hohlraum with Inertial confinement fusion in his study. His study in Laser ignition extends to Laser with its themes. Laser ignition is closely attributed to Laser in his research. His research on Thermodynamics frequently connects to adjacent areas such as Ignition system. As part of his studies on Ignition system, G. Erbert frequently links adjacent subjects like Thermodynamics.
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Efficient High-Power Laser Diodes
P. Crump;G. Erbert;H. Wenzel;C. Frevert.
IEEE Journal of Selected Topics in Quantum Electronics (2013)
Novel passivation process for the mirror facets of Al-free active-region high-power semiconductor diode lasers
P. Ressel;G. Erbert;U. Zeimer;K. Hausler.
IEEE Photonics Technology Letters (2005)
Diode-pumped mode-locked Yb:YCOB laser generating 35 fs pulses.
Akira Yoshida;Andreas Schmidt;Valentin Petrov;Christian Fiebig.
Optics Letters (2011)
Passively mode-locked Yb:KYWlaser pumped by a tapered diode laser.
Peter Klopp;Valentin Petrov;Uwe Griebner;Goetz Erbert.
Optics Express (2002)
High-Brightness Quantum Well Tapered Lasers
B. Sumpf;K.-H. Hasler;P. Adamiec;F. Bugge.
IEEE Journal of Selected Topics in Quantum Electronics (2009)
Directly diode-pumped holmium fiber lasers.
Stuart D. Jackson;F. Bugge;G. Erbert.
Optics Letters (2007)
High-power 808 nm lasers with a super-large optical cavity
A Knauer;G Erbert;R Staske;B Sumpf.
Semiconductor Science and Technology (2005)
Improved theory of the refractive-index change in quantum-well lasers
H. Wenzel;G. Erbert;P.M. Enders.
IEEE Journal of Selected Topics in Quantum Electronics (1999)
12 W high-brightness single-frequency DBR tapered diode laser
C. Fiebig;G. Blume;C. Kaspari;D. Feise.
Electronics Letters (2008)
20W continuous wave reliable operation of 980nm broad-area single emitter diode lasers with an aperture of 96μm
P. Crump;G. Blume;K. Paschke;R. Staske.
High-power lasers and applications (2009)
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