Nonlinear Propagation and Filamentation on 100 Meter Air Path of Femtosecond Beam Partitioned by Wire Mesh

Yuri E. Geints; Olga V. Minina; Ilia Yu Geints; Leonid V. Seleznev; Dmitrii V. Pushkarev; Daria V. Mokrousova; Georgy E. Rizaev; Daniil E. Shipilo; Irina A. Nikolaeva; Maria V. Kurilova; Nikolay A. Panov; Olga G. Kosareva; Aurélien Houard; Arnaud Couairon; Andrey A. Ionin; Weiwei Liu

doi:10.3390/s22176322

Nonlinear Propagation and Filamentation on 100 Meter Air Path of Femtosecond Beam Partitioned by Wire Mesh

Yuri E. Geints
, Olga V. Minina
, Ilia Yu Geints
, Leonid V. Seleznev
, Dmitrii V. Pushkarev
, Daria V. Mokrousova
, Georgy E. Rizaev
, Daniil E. Shipilo
, Irina A. Nikolaeva
, Maria V. Kurilova
, Nikolay A. Panov
, Olga G. Kosareva
, Aurélien Houard
, Arnaud Couairon
, Andrey A. Ionin
, Weiwei Liu

Research output: Contribution to journal › Article › peer-review

Abstract

High-intensity (∼1 TW/cm² and higher) region formed in the propagation of ∼60 GW, 90 fs Ti:Sapphire laser pulse on a ∼100 m path in air spans for several tens of meters and includes a plasma filament and a postfilament light channel. The intensity in this extended region is high enough to generate an infrared supercontinuum wing and to initiate laser-induced discharge in the gap between the electrodes. In the experiment and simulations, we delay the high-intensity region along the propagation direction by inserting metal-wire meshes with square cells at the laser system output. We identify the presence of a high-intensity region from the clean-spatial-mode distributions, appearance of the infrared supercontinuum wing, and occurrence of the laser-induced discharge. In the case of free propagation (without any meshes), the onset of the high-intensity zone is at 40–52 m from the laser system output with ∼30 m extension. Insertion of the mesh with 3 mm cells delays the beginning of the high-intensity region to 49–68 m with the same ∼30 m extension. A decrease in the cell size to 1 mm leads to both delay and shrinking of the high-intensity zone to 71–73 m and 6 m, respectively. Three-dimensional simulations in space confirm the mesh-induced delay of the high-intensity zone as the cell size decreases.

Original language	English
Article number	6322
Journal	Sensors (Switzerland)
Volume	22
Issue number	17
DOIs	https://doi.org/10.3390/s22176322
Publication status	Published - 1 Sept 2022

Keywords

beam regularization
femtosecond filamentation
infrared supercontinuum
remote discharge triggering

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10.3390/s22176322

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Geints, Y. E., Minina, O. V., Geints, I. Y., Seleznev, L. V., Pushkarev, D. V., Mokrousova, D. V., Rizaev, G. E., Shipilo, D. E., Nikolaeva, I. A., Kurilova, M. V., Panov, N. A., Kosareva, O. G., Houard, A., Couairon, A., Ionin, A. A., & Liu, W. (2022). Nonlinear Propagation and Filamentation on 100 Meter Air Path of Femtosecond Beam Partitioned by Wire Mesh. Sensors (Switzerland), 22(17), Article 6322. https://doi.org/10.3390/s22176322

@article{acc8494ced354a92b816aac922460ebe,

title = "Nonlinear Propagation and Filamentation on 100 Meter Air Path of Femtosecond Beam Partitioned by Wire Mesh",

abstract = "High-intensity (∼1 TW/cm2 and higher) region formed in the propagation of ∼60 GW, 90 fs Ti:Sapphire laser pulse on a ∼100 m path in air spans for several tens of meters and includes a plasma filament and a postfilament light channel. The intensity in this extended region is high enough to generate an infrared supercontinuum wing and to initiate laser-induced discharge in the gap between the electrodes. In the experiment and simulations, we delay the high-intensity region along the propagation direction by inserting metal-wire meshes with square cells at the laser system output. We identify the presence of a high-intensity region from the clean-spatial-mode distributions, appearance of the infrared supercontinuum wing, and occurrence of the laser-induced discharge. In the case of free propagation (without any meshes), the onset of the high-intensity zone is at 40–52 m from the laser system output with ∼30 m extension. Insertion of the mesh with 3 mm cells delays the beginning of the high-intensity region to 49–68 m with the same ∼30 m extension. A decrease in the cell size to 1 mm leads to both delay and shrinking of the high-intensity zone to 71–73 m and 6 m, respectively. Three-dimensional simulations in space confirm the mesh-induced delay of the high-intensity zone as the cell size decreases.",

keywords = "beam regularization, femtosecond filamentation, infrared supercontinuum, remote discharge triggering",

author = "Geints, \{Yuri E.\} and Minina, \{Olga V.\} and Geints, \{Ilia Yu\} and Seleznev, \{Leonid V.\} and Pushkarev, \{Dmitrii V.\} and Mokrousova, \{Daria V.\} and Rizaev, \{Georgy E.\} and Shipilo, \{Daniil E.\} and Nikolaeva, \{Irina A.\} and Kurilova, \{Maria V.\} and Panov, \{Nikolay A.\} and Kosareva, \{Olga G.\} and Aur{\'e}lien Houard and Arnaud Couairon and Ionin, \{Andrey A.\} and Weiwei Liu",

note = "Publisher Copyright: {\textcopyright} 2022 by the authors.",

year = "2022",

month = sep,

day = "1",

doi = "10.3390/s22176322",

language = "English",

volume = "22",

journal = "Sensors (Switzerland)",

issn = "1424-8220",

number = "17",

}

Geints, YE, Minina, OV, Geints, IY, Seleznev, LV, Pushkarev, DV, Mokrousova, DV, Rizaev, GE, Shipilo, DE, Nikolaeva, IA, Kurilova, MV, Panov, NA, Kosareva, OG, Houard, A , Couairon, A, Ionin, AA & Liu, W 2022, 'Nonlinear Propagation and Filamentation on 100 Meter Air Path of Femtosecond Beam Partitioned by Wire Mesh', Sensors (Switzerland), vol. 22, no. 17, 6322. https://doi.org/10.3390/s22176322

TY - JOUR

T1 - Nonlinear Propagation and Filamentation on 100 Meter Air Path of Femtosecond Beam Partitioned by Wire Mesh

AU - Geints, Yuri E.

AU - Minina, Olga V.

AU - Geints, Ilia Yu

AU - Seleznev, Leonid V.

AU - Pushkarev, Dmitrii V.

AU - Mokrousova, Daria V.

AU - Rizaev, Georgy E.

AU - Shipilo, Daniil E.

AU - Nikolaeva, Irina A.

AU - Kurilova, Maria V.

AU - Panov, Nikolay A.

AU - Kosareva, Olga G.

AU - Houard, Aurélien

AU - Couairon, Arnaud

AU - Ionin, Andrey A.

AU - Liu, Weiwei

PY - 2022/9/1

Y1 - 2022/9/1

N2 - High-intensity (∼1 TW/cm2 and higher) region formed in the propagation of ∼60 GW, 90 fs Ti:Sapphire laser pulse on a ∼100 m path in air spans for several tens of meters and includes a plasma filament and a postfilament light channel. The intensity in this extended region is high enough to generate an infrared supercontinuum wing and to initiate laser-induced discharge in the gap between the electrodes. In the experiment and simulations, we delay the high-intensity region along the propagation direction by inserting metal-wire meshes with square cells at the laser system output. We identify the presence of a high-intensity region from the clean-spatial-mode distributions, appearance of the infrared supercontinuum wing, and occurrence of the laser-induced discharge. In the case of free propagation (without any meshes), the onset of the high-intensity zone is at 40–52 m from the laser system output with ∼30 m extension. Insertion of the mesh with 3 mm cells delays the beginning of the high-intensity region to 49–68 m with the same ∼30 m extension. A decrease in the cell size to 1 mm leads to both delay and shrinking of the high-intensity zone to 71–73 m and 6 m, respectively. Three-dimensional simulations in space confirm the mesh-induced delay of the high-intensity zone as the cell size decreases.

AB - High-intensity (∼1 TW/cm2 and higher) region formed in the propagation of ∼60 GW, 90 fs Ti:Sapphire laser pulse on a ∼100 m path in air spans for several tens of meters and includes a plasma filament and a postfilament light channel. The intensity in this extended region is high enough to generate an infrared supercontinuum wing and to initiate laser-induced discharge in the gap between the electrodes. In the experiment and simulations, we delay the high-intensity region along the propagation direction by inserting metal-wire meshes with square cells at the laser system output. We identify the presence of a high-intensity region from the clean-spatial-mode distributions, appearance of the infrared supercontinuum wing, and occurrence of the laser-induced discharge. In the case of free propagation (without any meshes), the onset of the high-intensity zone is at 40–52 m from the laser system output with ∼30 m extension. Insertion of the mesh with 3 mm cells delays the beginning of the high-intensity region to 49–68 m with the same ∼30 m extension. A decrease in the cell size to 1 mm leads to both delay and shrinking of the high-intensity zone to 71–73 m and 6 m, respectively. Three-dimensional simulations in space confirm the mesh-induced delay of the high-intensity zone as the cell size decreases.

KW - beam regularization

KW - femtosecond filamentation

KW - infrared supercontinuum

KW - remote discharge triggering

U2 - 10.3390/s22176322

DO - 10.3390/s22176322

M3 - Article

C2 - 36080786

AN - SCOPUS:85137573308

SN - 1424-8220

VL - 22

JO - Sensors (Switzerland)

JF - Sensors (Switzerland)

IS - 17

M1 - 6322

ER -

Nonlinear Propagation and Filamentation on 100 Meter Air Path of Femtosecond Beam Partitioned by Wire Mesh

Abstract

Keywords

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