We report on an improved ytterbium-doped yttrium aluminum garnet thin-disk multi-pass amplifier for kilowatt-level ultrafast lasers,showcasing excellent beam quality.At a repetition rate of 800 kHz,the 6.8 ps,276 W se...We report on an improved ytterbium-doped yttrium aluminum garnet thin-disk multi-pass amplifier for kilowatt-level ultrafast lasers,showcasing excellent beam quality.At a repetition rate of 800 kHz,the 6.8 ps,276 W seed laser is amplified up to an average power of 1075 W,corresponding to a pulse energy of 1.34 mJ.The 36-pass amplifier is designed as a compact mirror array in which the beam alternately propagates between the mirrors and the disk by a quasi-collimated state.We adopted a quasi-collimated propagation to confine stray and diffracted light by the slight curvature of the disk,which enables us to achieve an outstanding extraction efficiency of up to 57%with excellent beam quality in stable laser operation at high power.The beam quality at 1075 W was measured to be M^(2)<1.51.Furthermore,stability testing was demonstrated with a root-mean-square power fiuctuation of less than 1.67%for 10 min.展开更多
We present a new method that can be used to calculate pulse-front distortion by measuring the spectral interference of two point-diffraction fields in their overlapped district. We demonstrate, for the first time, the...We present a new method that can be used to calculate pulse-front distortion by measuring the spectral interference of two point-diffraction fields in their overlapped district. We demonstrate, for the first time, the measurement of the pulse-front distortion of the pulse from a complex multi-pass amplification system, which exists in almost all high-power laser systems, and obtain the irregular pulse-front distribution. The method presented does not need any reference light or assumption about the pulse-front distribution, and has an accuracy of several femtoseconds.展开更多
基金supported by the National Key Research and Development Program of China(2022YFB3605800)National Natural Science Foundation of China(62105225,62275174,61975136,61935014)+3 种基金Shenzhen University Stability Support Project(20220719104008001)Natural Science Foundation of Top Talent of Shenzhen Technology University(GDRC202106)Pingshan Special Funds for Scientific and Technological Innovation(PSKG202003,PSKG202007)Guangdong Provincial Engineering Technology Research Center for Materials for Advanced MEMS Sensor Chip(2022GCZX005)。
文摘We report on an improved ytterbium-doped yttrium aluminum garnet thin-disk multi-pass amplifier for kilowatt-level ultrafast lasers,showcasing excellent beam quality.At a repetition rate of 800 kHz,the 6.8 ps,276 W seed laser is amplified up to an average power of 1075 W,corresponding to a pulse energy of 1.34 mJ.The 36-pass amplifier is designed as a compact mirror array in which the beam alternately propagates between the mirrors and the disk by a quasi-collimated state.We adopted a quasi-collimated propagation to confine stray and diffracted light by the slight curvature of the disk,which enables us to achieve an outstanding extraction efficiency of up to 57%with excellent beam quality in stable laser operation at high power.The beam quality at 1075 W was measured to be M^(2)<1.51.Furthermore,stability testing was demonstrated with a root-mean-square power fiuctuation of less than 1.67%for 10 min.
基金Project supported by the National Natural Science Foundation of China (Grant Nos. 10904132 and 11074225)the National Defense Science Technology Foundation of State Key Laboratory of High Temperature and Density Plasma Physics,China (Grant No. 9140C680604110C6805)
文摘We present a new method that can be used to calculate pulse-front distortion by measuring the spectral interference of two point-diffraction fields in their overlapped district. We demonstrate, for the first time, the measurement of the pulse-front distortion of the pulse from a complex multi-pass amplification system, which exists in almost all high-power laser systems, and obtain the irregular pulse-front distribution. The method presented does not need any reference light or assumption about the pulse-front distribution, and has an accuracy of several femtoseconds.
