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- Author: Yu Yang
- Publisher: LAP Lambert Academic Publishing
- ISBN-10: 3659649392
- ISBN-13: 9783659649394
- Format: 15.2 x 22.9 x 1.1 cm, minkšti viršeliai
- Language: English
- SAVE -10% with code: EXTRA
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Description
Ultrafast (UF) mode-locked (ML) lasers are extremely powerful tools in scientific research and industrial applications including material processing, nonlinear optics, attosecond science, metrology, etc. The most popular UF Ti: sapphire laser applications are limited by its high ownership cost, system complexity and low power transfer efficiency. Yb3+: CaF2 has been recognized as a promising candidate for a high efficient and high power femtosecond laser, for its simple energy-level scheme, high quantum efficiency ( 1), very small quantum defect (70 nm), high thermal conductivity and compatibility with high power InGaAs diode pumping. Two types of Yb3+: CaF2 ML resonators based on semiconductor saturable absorber mirrors (SESAM's) and Kerr lens mode-locking (KLM) have been demonstrated and analyzed in detail. A Kerr-lens ML oscillator was constructed for continuous-wave modelocking operations by incorporating an additional optical element with an enhanced nonlinear Kerr coefficient, which represents the first such investigation for an Yb3+: CaF2 oscillator to our best knowledge.
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- Author: Yu Yang
- Publisher: LAP Lambert Academic Publishing
- ISBN-10: 3659649392
- ISBN-13: 9783659649394
- Format: 15.2 x 22.9 x 1.1 cm, minkšti viršeliai
- Language: English English
Ultrafast (UF) mode-locked (ML) lasers are extremely powerful tools in scientific research and industrial applications including material processing, nonlinear optics, attosecond science, metrology, etc. The most popular UF Ti: sapphire laser applications are limited by its high ownership cost, system complexity and low power transfer efficiency. Yb3+: CaF2 has been recognized as a promising candidate for a high efficient and high power femtosecond laser, for its simple energy-level scheme, high quantum efficiency ( 1), very small quantum defect (70 nm), high thermal conductivity and compatibility with high power InGaAs diode pumping. Two types of Yb3+: CaF2 ML resonators based on semiconductor saturable absorber mirrors (SESAM's) and Kerr lens mode-locking (KLM) have been demonstrated and analyzed in detail. A Kerr-lens ML oscillator was constructed for continuous-wave modelocking operations by incorporating an additional optical element with an enhanced nonlinear Kerr coefficient, which represents the first such investigation for an Yb3+: CaF2 oscillator to our best knowledge.
Reviews