Postfilament supercontinuum on 100 m path in air

Postfilament supercontinuum on 100 m path in air

Pulses at 744 nm with 90 fs duration, 6 mJ energy, and a weakly divergent wavefront propagate for more than 100 m and generate a filament followed by an unprecedently long high intensity (>= 1 TW/cm(2)) light channel. Over a 20 m long sub-section of this channel, the pulse energy is transferred c...

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Veröffentlicht in:Optics letters 2021-03, Vol.46 (5), p.1125-1128
Hauptverfasser: Kosareva, O., Panov, N., Shipilo, D., Mokrousova, D., Nikolaeva, Mitina, E., Koribut, A., Reutov, A., Rizaev, G., Couairon, A., Houard, A., Skryabin, D., Saletskiy, A., Savel'ev, A., Seleznev, L., Ionin, A., Chin, S. L.
Format: Artikel
Sprache:eng
Schlagworte:
Femtosecond pulses
Luminous intensity
Optics
Physical Sciences
Physics
Pulse propagation
Science & Technology
Wave fronts
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Zusammenfassung:Pulses at 744 nm with 90 fs duration, 6 mJ energy, and a weakly divergent wavefront propagate for more than 100 m and generate a filament followed by an unprecedently long high intensity (>= 1 TW/cm(2)) light channel. Over a 20 m long sub-section of this channel, the pulse energy is transferred continuously to the infrared wing, forming spectral humps that extend up to 850 nm. From 3D+time carrier-resolved simulations of 100 m pulse propagation, we show that spectral humps indicate the formation of a train of femtosecond pulses appearing at a predictable position in the propagation path. (C) 2021 Optical Society of America
ISSN:0146-9592
1539-4794
DOI:10.1364/OL.416224