High-contrast 20 Petawatt Ti:sapphire laser system

Chu, Yuxi; Liang, Xiaoyan; Yu, Lianghong; Xu, Yi; Xu, Lu; Ma, Lin; Lu, Xiaoming; Liu, Yanqi; Leng, Yuxin; Li, Ruxin; Xu, Zhizhan

doi:10.1364/oe.21.029231

Cited by 124 publications

(57 citation statements)

References 19 publications

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“…Using the technique of laser energy extraction during pumping, more than 70-J energy has been obtained at the output of the final multi-pass Ti:sapphire amplifier of a 2 PW laser system, pumped by 140 J pulse energy green laser [6]. Parasitic lasing was suppressed up to 150 J pumping.…”

Section: High Energy Ti:sapphire Amplificationmentioning

confidence: 99%

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High power femtosecond lasers at ELI-NP

Dabu

2015

AIP Conference Proceedings

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Section: High Energy Ti:sapphire Amplificationmentioning

confidence: 99%

“…Recently, PW-class Ti:sapphire have been demonstrated worldwide [2][3][4][5][6]. Till now, the highest peak intensity of 2 x 10 22 W/cm 2 was reported by focusing the 300 TW beam of a Ti:sapphire femtosecond laser using f/1 optics [7].…”

Section: Introducerementioning

confidence: 99%

High power femtosecond lasers at ELI-NP

Dabu

2015

AIP Conference Proceedings

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“…Such high peak power laser systems are used to study high harmonics generation, white light continuum generation, plasma and optical field ionization [12][13][14]. A rapid advancement in the development of high-average-peak power CPA laser systems [11,[14][15][16] has been observed in recent years. However, many technical issues related to development and characterization needs to be addressed.…”

Section: Introductionmentioning

confidence: 99%

Thermal Lensing Compensation in the Development of 30 fs Pulse Duration Chirped Pulse Amplification Laser System and Single-Shot Intensity-Phase Measurement

Imran

Hussain

2018

Acta Phys. Pol. A

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We present 30 fs pulse duration home-made chirped pulse amplification Ti:sapphire laser system operating at a repetition rate of 1 kHz with 4.0 mJ pulse energy. The Ti:sapphire laser system with ∼ 819 nm center wavelength has a long-cavity oscillator, four pass grating stretcher, 8-pass pre-amplifier, 4-pass post-amplifier and a double pass grating compressor. The Peltier coolers and thermal eigenmode post-amplifier are introduced to compensate the thermal lensing of the crystal in the amplifiers and to enhance the beam focusability on the crystal. The Strehl ratio and M 2 value measured by employing the Shack-Hartman wavefront sensor HASO4 to observe the spatial profile and beam quality. The most sensitive single-shot second harmonic generation frequency-resolved optical gating diagnostic technique is employed to characterize intensity and phase of the output compressed laser pulses.

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“…Based on the technique of chirp-pulse amplification (CPA) [22], the technology of table-top 100-TW-class laser is being developed continuously [23][24][25][26][27][28][29][30][31][32][33][34], and lasers with petawatt peak power are built at large research centers [35][36][37][38][39][40][41][42][43][44]. In the meantime, as the complexity of experiments increases, there is a growing need for precision control of laser-plasma interaction in the application of high-intensity lasers.…”

Section: Introductionmentioning

confidence: 99%

A 110-TW multiple-beam laser system with a 5-TW wavelength-tunable auxiliary beam for versatile control of laser-plasma interaction

et al. 2014

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A Ti:sapphire laser system has been constructed with two synchronized main beams of 110 TW and 13 TW, and a 5-TW wavelength-tunable synchronized auxiliary beam for versatile control of laser-plasma interaction. The first main beam provides 3.3-J, 30-fs, 810-nm pulses, and the second 450-mJ, 34-fs, 805-nm pulses. The auxiliary beam comes from amplified spectral windows selected from a supercontinuum of high spatial coherence and provides 38-fs pulses with tunable wavelengths (870-920 nm). The two main beams can be focused down to M 2 = 1.2 and 1.1, with 77 and 81 % energy enclosed in the focal spots, respectively. The energy fluctuations are 1.1 and 1.8 %, and the pointing fluctuations are 4.5 and 4.8 lrad, respectively. By using a preamplifier and saturable absorber before the pulse stretcher to suppress amplified spontaneous emission, the temporal contrast of the 110-TW main beam reaches 4 Â 10 À10 at the -100-ps timescale. Even though the auxiliary beam is generated from a highly nonlinear process, by confining the supercontinuum generation in a single self-trapping filament, a spatial coherence close to the main beams can be achieved. It can be focused down to M 2 = 1.3, with 72 % energy enclosed in the focal spot. The energy fluctuation is 2.6 %, and the pointing fluctuation is 4.7 lrad. The versatility of synchronized multiple-beams with tunable wavelengths, good energy and pointing stability, and the spatiotemporal quality of the laser system has been essential to our experiments in high-harmonic generation, extreme-UV lasers, and laser-wakefield accelerators in which precision control of laser-plasma interaction is facilitated by a concerted sequence of driving pulses.

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High-contrast 20 Petawatt Ti:sapphire laser system

Cited by 124 publications

References 19 publications

High power femtosecond lasers at ELI-NP

High power femtosecond lasers at ELI-NP

Thermal Lensing Compensation in the Development of 30 fs Pulse Duration Chirped Pulse Amplification Laser System and Single-Shot Intensity-Phase Measurement

A 110-TW multiple-beam laser system with a 5-TW wavelength-tunable auxiliary beam for versatile control of laser-plasma interaction

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