B. G. Bravy scite author profile

B. G. Bravy

4Publications

54Citation Statements Received

76Citation Statements Given

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126

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Affiliations

Institute of Problems of Chemical Physics, Lomonosov Moscow State University, Russian Academy of Sciences

Publications

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Controlled energy deposition and void-like modification inside transparent solids by two-color tightly focused femtosecond laser pulses

Potemkin

Mareev

Bezsudnova

et al. 2017

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We report a bulk void-like micromodification of fused silica using two-color μJ-energy level tightly focused (NA = 0.5) co-propagating seeding (visible, 0.62 μm) and heating (near-IR, 1.24 μm) femtosecond laser pulses with online third harmonic diagnostics of created microplasmas as well as subsequent laser-induced void-like defects. It has been shown experimentally and theoretically that production of seeding electrons through multiphoton ionization by visible laser pulses paves the way for controllability of the energy deposition and laser-induced micromodification via carrier heating by delayed infrared laser pulses inside the material. Experimental results demonstrate wide possibilities to increase the density of energy deposited up to 6 kJ cm−3 inside the dielectric by tight focusing of two color fs-laser pulses and elliptical polarization for infrared heating fs-laser pulses. The developed theoretical approach predicts the enhancement of deposited energy density up to 9 kJ cm−3 using longer (mid-IR) wavelengths for heating laser pulses.

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35-mJ 150-fs Fe:ZnSe hybrid mid-IR femtosecond laser at 44 μm for driving extreme nonlinear optics

et al. 2019

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Overcritical plasma ignition and diagnostics from oncoming interaction of two color low energy tightly focused femtosecond laser pulses inside fused silica

et al. 2016

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We report overcritical (3.3 × 1021 cm−3) microplasma produced by low energy colliding IR (infrared) (1.24 μm) and visible (0.62 μm) femtosecond pulses tightly focused (NA = 0.5) into the bulk of fused silica with on-line monitoring based on third harmonic generated by the IR beam. It was established that the absorbed energy density is the key parameter that determines the micromodification formation threshold and in our experimental conditions it is close to 4.5 kJ cm−3. Non-monotonic behavior of the third harmonic signal as a function of time delay between visible (0.62 μm) and IR (1.24 μm) femtosecond pulses demonstrates the qualitative differences about the two phenomena: one is the seed electrons generation by the visible pulse via multiphoton ionization and second is the avalanche ionization by the IR pulse. We predict that the tandem two-color excitation of wide-bandgap dielectric in comparison with single-color pulse interaction regime allows providing a much higher absorbed energy density and overcritical plasma.

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Toward a sub-terawatt mid-IR (4–5μm) femtosecond hybrid laser system based on parametric seed pulse generation and amplification in Fe²⁺:ZnSe

et al. 2015

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For the first time, an experimentally measured seed pulse gain of about 2 cm−1 allows possibilities in the scaling power of such a femtosecond laser system in terawatts. The concept of a subterawatt power level hybrid femtosecond mid-IR (4–5 μm) laser system, based on a weak pulse from an optical parametric mid-IR seeder that is amplified in chalcogenide monocrystalline Fe2+:ZnSe, to gain medium has been proposed and designed. The method and approach for optimizing the choice of nonlinear medium, its length, and the required light intensity for the efficient non-linear self-compression of an ultrashort pulse has also been proposed and considered.

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B. G. Bravy

Controlled energy deposition and void-like modification inside transparent solids by two-color tightly focused femtosecond laser pulses

35-mJ 150-fs Fe:ZnSe hybrid mid-IR femtosecond laser at 44 μm for driving extreme nonlinear optics

Overcritical plasma ignition and diagnostics from oncoming interaction of two color low energy tightly focused femtosecond laser pulses inside fused silica

Toward a sub-terawatt mid-IR (4–5μm) femtosecond hybrid laser system based on parametric seed pulse generation and amplification in Fe²⁺:ZnSe

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About

B. G. Bravy

Controlled energy deposition and void-like modification inside transparent solids by two-color tightly focused femtosecond laser pulses

35-mJ 150-fs Fe:ZnSe hybrid mid-IR femtosecond laser at 44 μm for driving extreme nonlinear optics

Overcritical plasma ignition and diagnostics from oncoming interaction of two color low energy tightly focused femtosecond laser pulses inside fused silica

Toward a sub-terawatt mid-IR (4–5μm) femtosecond hybrid laser system based on parametric seed pulse generation and amplification in Fe2+:ZnSe

Contact Info

Product

Resources

About

Toward a sub-terawatt mid-IR (4–5μm) femtosecond hybrid laser system based on parametric seed pulse generation and amplification in Fe²⁺:ZnSe