Large-amplitude electromagnetic radiofrequency fields are created by the charge-separation induced in interactions of high-intensity, short-pulse lasers with solid targets and have inte

Large-amplitude electromagnetic radiofrequency fields are created by the charge-separation induced in interactions of high-intensity, short-pulse lasers with solid targets and have intensity that decreases with the distance from target. Alternatively, it was experimentally proved very recently that charged particles emitted by petawatt laser-target interactions can be deposited on a capacitor-collector structure, far away from the target, and lead to the rapid (nanoseconds scale) generation of large quasi-static electric fields (MV/m), over wide regions. We demonstrate here the generation of both these two type of fields in experiments at the PHELIX Laser, with ∽100 J energy and ∽10¹⁹ W/cm² intensity, for picoseconds laser pulses. Quasi-static fields, up to tens of kV/m, were here observed at distances larger than 1 m from target and resulted much higher than the radiofrequency component. This is of primary importance for inertial-confinement-fusion and laser-plasma-acceleration and also for promising applications to different scenarios.show less

We proposed an aperiodic laser beam distribution, in which the laser beams are placed along Fermat spiral, to suppress the sidelobe power in the coherent beam combining. Owing to the ch

We proposed an aperiodic laser beam distribution, in which the laser beams are placed along Fermat spiral, to suppress the sidelobe power in the coherent beam combining. Owing to the changed distances between two consecutive beams, the condition of the sidelobe suppression are naturally satisfied. The Fermat spiral array were demonstrated to achieved a better sidelobe suppression than the periodic arrays, and the effects of various factors on the sidelobe suppression were analyzed numerically. Experiments were carried out to verify the sidelobe suppression by different Fermat spiral arrays and the results matched well with the simulations.show less

Large area and uniform monolayer MoS2 is of great importance for optoelectronic devices but is commonly suffering from rather weak photoluminescence. Here, by engineering the concentrat

Large area and uniform monolayer MoS2 is of great importance for optoelectronic devices but is commonly suffering from rather weak photoluminescence. Here, by engineering the concentration profiles of gaseous chemicals through extra trace amount of water, we demonstrate the uniform dendrite-type growth of monolayers MoS2 unraveled by the spatially resolved fluorescence spectroscopy, which exhibits macroscopic monolayer flakes (up to centimeter scale) with photoluminescence intensity of orders of magnitude higher than conventional CVD monolayers MoS2. Both spectroscopic evidence and theoretical models reveal that the fast-fractal dendrite growth can be ascribed to the extra introduced water sources that generate sufficient aqueous gas around the S-poor regions nearby the central-axis zone, leading to highly efficient Mo sources transport, accelerated S atom corrosion nearby grain edges and/or defect sites, as well as enhanced photoemission intensity. Our results may provide new insight for high throughput fabrication of MoS2 monolayers with high yield photoluminescence efficiency.show less

A hundred-watt level spatial mode switchable all-fiber laser is demonstrated based on a master oscillator power amplifier scheme. The performance of the amplifier with two seed lasers,

A hundred-watt level spatial mode switchable all-fiber laser is demonstrated based on a master oscillator power amplifier scheme. The performance of the amplifier with two seed lasers, i.e., with the acoustically induced fiber grating (AIFG) mode converter inside and outside of the seed laser cavity, is investigated. Real-time mode switching with millisecond scale switching time between LP₀₁ and LP₁₁ mode while operating in full power (> 100 W) is realized through an AIFG driven by radio frequency modulation. This work could provide a good reference for realizing high-power agile mode switchable fiber lasers for practical applications.show less