In this work,we confirm a Pr^(3+):LiYF_(4)pulsed laser with high power and high energy at 639 nm based on the acoustooptic cavity dumping technique.The maximum average output power,narrowest pulse width,highest pulse ...In this work,we confirm a Pr^(3+):LiYF_(4)pulsed laser with high power and high energy at 639 nm based on the acoustooptic cavity dumping technique.The maximum average output power,narrowest pulse width,highest pulse energy and peak power of the pulsed laser at a repetition rate of 0.1 kHz are 532 mW,112 ns,5.32 mJ and 47.5 kW,respectively.A 639 nm pulsed laser with such high pulse energy and peak power has not been reported previously.Furthermore,we obtain a widely tunable range of repetition rates from 0.1 to 5000 kHz.The diffracted beam quality factors M^(2) are 2.18(in the x direction)and 2.04(in the y direction).To the best of our knowledge,this is the first time that a cavity-dumped all-solid-state pulsed laser in the visible band has been reported.This work provides a promising method for obtaining high-performance pulsed lasers.展开更多
Since the advent of femtosecond lasers,performance improvements have constantly impacted on existing applications and enabled novel applications.However,one performance feature bearing the potential of a quantum leap ...Since the advent of femtosecond lasers,performance improvements have constantly impacted on existing applications and enabled novel applications.However,one performance feature bearing the potential of a quantum leap for high-field applications is still not available:the simultaneous emission of extremely high peak and average powers.Emerging applications such as laser particle acceleration require exactly this performance regime and,therefore,challenge laser technology at large.On the one hand,canonical bulk systems can provide pulse peak powers in the multi-terawatt to petawatt range,while on the other hand,advanced solid-state-laser concepts such as the thin disk,slab or fibre are well known for their high efficiency and their ability to emit high average powers in the kilowatt range with excellent beam quality.In this contribution,a compact laser system capable of simultaneously providing high peak and average powers with high wall-plug efficiency is proposed and analysed.The concept is based on the temporal coherent combination(pulse stacking)of a pulse train emitted from a high-repetition-rate femtosecond laser system in a passive enhancement cavity.Thus,the pulse energy is increased at the cost of the repetition rate while almost preserving the average power.The concept relies on a fast switching element for dumping the enhanced pulse out of the cavity.The switch constitutes the key challenge of our proposal.Addressing this challenge could,for the first time,allow the highly efficient dumping of joule-class pulses at megawatt average power levels and lead to unprecedented laser parameters.展开更多
A multi-operation laser oscillator is developed and built with multiple operation modes (OMs): injection- seeding mode, cavity-dumping mode and Q-switching mode. With the same electrical energy pumping, the multi- ...A multi-operation laser oscillator is developed and built with multiple operation modes (OMs): injection- seeding mode, cavity-dumping mode and Q-switching mode. With the same electrical energy pumping, the multi- operation laser oscillator provides different output energies and pulse durations for different OMs. In the Q-switching mode, the output coupling is optimized for different electrical energy pumping. The laser oscillator operation can be switched between different modes conveniently. The multi-operation laser sources could be operated in multiple OMs for various research and application requirements.展开更多
基金supported by the National Natural Science Foundation of China(Grant Nos.62465006 and 61975168).
文摘In this work,we confirm a Pr^(3+):LiYF_(4)pulsed laser with high power and high energy at 639 nm based on the acoustooptic cavity dumping technique.The maximum average output power,narrowest pulse width,highest pulse energy and peak power of the pulsed laser at a repetition rate of 0.1 kHz are 532 mW,112 ns,5.32 mJ and 47.5 kW,respectively.A 639 nm pulsed laser with such high pulse energy and peak power has not been reported previously.Furthermore,we obtain a widely tunable range of repetition rates from 0.1 to 5000 kHz.The diffracted beam quality factors M^(2) are 2.18(in the x direction)and 2.04(in the y direction).To the best of our knowledge,this is the first time that a cavity-dumped all-solid-state pulsed laser in the visible band has been reported.This work provides a promising method for obtaining high-performance pulsed lasers.
基金This work has been partly supported by the German Federal Ministry of Education and Research(BMBF)under contract 13N12082‘NEXUS’,by the Thuringian Ministry of Education,Science and Culture(TMBWK)under contract 12037-515‘BURST’by the European Research Council under the ERC grant agreement no.[617173]‘ACOPS’+3 种基金by the Deutsche Forschungsgemeinschaft Cluster of Excellence‘Munich-Centre for Advanced Photonics’(munich-photonics.de).AK acknowledges financial support by the Helmholtz-Institute Jena.TE acknowledges financial support by the CarlZeiss-Stiftung.IP and SH acknowledge financial support by the BMBF under PhoNa-Photonische Nanomaterialien,contract number 03IS2101B.
文摘Since the advent of femtosecond lasers,performance improvements have constantly impacted on existing applications and enabled novel applications.However,one performance feature bearing the potential of a quantum leap for high-field applications is still not available:the simultaneous emission of extremely high peak and average powers.Emerging applications such as laser particle acceleration require exactly this performance regime and,therefore,challenge laser technology at large.On the one hand,canonical bulk systems can provide pulse peak powers in the multi-terawatt to petawatt range,while on the other hand,advanced solid-state-laser concepts such as the thin disk,slab or fibre are well known for their high efficiency and their ability to emit high average powers in the kilowatt range with excellent beam quality.In this contribution,a compact laser system capable of simultaneously providing high peak and average powers with high wall-plug efficiency is proposed and analysed.The concept is based on the temporal coherent combination(pulse stacking)of a pulse train emitted from a high-repetition-rate femtosecond laser system in a passive enhancement cavity.Thus,the pulse energy is increased at the cost of the repetition rate while almost preserving the average power.The concept relies on a fast switching element for dumping the enhanced pulse out of the cavity.The switch constitutes the key challenge of our proposal.Addressing this challenge could,for the first time,allow the highly efficient dumping of joule-class pulses at megawatt average power levels and lead to unprecedented laser parameters.
文摘A multi-operation laser oscillator is developed and built with multiple operation modes (OMs): injection- seeding mode, cavity-dumping mode and Q-switching mode. With the same electrical energy pumping, the multi- operation laser oscillator provides different output energies and pulse durations for different OMs. In the Q-switching mode, the output coupling is optimized for different electrical energy pumping. The laser oscillator operation can be switched between different modes conveniently. The multi-operation laser sources could be operated in multiple OMs for various research and application requirements.
