G. Mourou scite author profile

The electromagnetic radiation pressure becomes dominant in the interaction of the ultra-intense electromagnetic wave with a solid material, thus the wave energy can be transformed efficiently into the energy of ions representing the material and the high density ultra-short relativistic ion beam is generated. This regime can be seen even with present-day technology, when an exawatt laser will be built. As an application, we suggest the laser-driven heavy ion collider.

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Compression of amplified chirped optical pulses

Strickland

Mourou

1985

Optics Communications

977

522

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Ultra-high intensity- 300-TW laser at 0.1 Hz repetition rate

et al. 2008

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Femtosecond Optical Breakdown in Dielectrics

et al. 1998

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We report measurements of the optical breakdown threshold and ablation depth in dielectrics with different band gaps for laser pulse durations ranging from 5 ps to 5 fs at a carrier wavelength of 780 nm. For t , 100 fs, the dominant channel for free electron generation is found to be either impact or multiphoton ionization (MPI) depending on the size of the band gap. The observed MPI rates are substantially lower than those predicted by the Keldysh theory. We demonstrate that sub-10-fs laser pulses open up the way to reversible nonperturbative nonlinear optics (at intensities greater than 10 14 W͞cm 2 slightly below damage threshold) and to nanometer-precision laser ablation (slightly above threshold) in dielectric materials. [S0031-9007(98)05969-9] PACS numbers: 79.20.Ds, 42.65.Re, 78.47. + pLaser-induced breakdown resulting in damage to dielectrics has been the subject of extensive experimental and theoretical investigations since powerful lasers became available [1-3]. It has been described in terms of three major processes: (i) the excitation of electrons in the conduction band by impact and multiphoton ionization (MPI), (ii) heating of the conduction-band (henceforth free) electrons by the radiation, and (iii) transfer of the plasma energy to the lattice. For pulses of a few picoseconds or shorter, heat diffusion is "frozen" during the interaction [4] and the shocklike energy deposition leads to ablation. This new regime of laser-matter interactions holds promise for a number of intriguing applications in science and technology.Although breakdown experiments were recently extended to the subpicosecond regime [5-9], both the nature of the avalanche and the role of multiphoton ionization have remained controversial up to now. Du et al. [5] were the first to observe a deviation from the p t scaling of breakdown threshold fluence F th and an increasingly deterministic character of breakdown for t , 10 ps as opposed to longer pulses. These observations were explained in terms of an avalanche scaling with the square root of the laser intensity, and MPI was found to serve only for the production of seed electrons for the avalanche. By contrast, Stuart et al. 's model [6] yields an avalanche that scales linearly with the laser intensity. Combining this model with the Keldysh MPI rate [10], these investigators found that MPI is likely to become the dominant channel for free electron generation for t , 100 fs, which was predicted to result in F th as low as ,0.1 J͞cm 2 for t ഠ 10 fs in fused silica. In this Letter, we report F th ഠ 1.5 J͞cm 2 in fused silica for t # 10 fs. Our investigations confirm a linear scaling of the avalanche with intensity [6] and yield MPI rates which are orders of magnitude lower than predicted by Keldysh's theory [11].This work significantly extends previous studies of ultrashort-pulse-induced breakdown in several respects.The pulses for femtosecond breakdown experiments are delivered by a spatially filtered beam for the first time. The high-quality beam and the absence of heat diffusion a...

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Self-channeling of high-peak-power femtosecond laser pulses in air

et al. 1995

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Laser ablation and micromachining with ultrashort laser pulses

Liu

Mourou

1997

IEEE J. Quantum Electron.

871

447

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G. Mourou

Compression of amplified chirped optical pulses

Optics in the relativistic regime

Highly Efficient Relativistic-Ion Generation in the Laser-Piston Regime

Compression of amplified chirped optical pulses

Ultra-high intensity- 300-TW laser at 0.1 Hz repetition rate

Femtosecond Optical Breakdown in Dielectrics

Self-channeling of high-peak-power femtosecond laser pulses in air

Laser ablation and micromachining with ultrashort laser pulses

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