Ultrabroadband microwave radiation from near- and mid-infrared laser-produced plasmas in air

An ultrashort laser pulse focused in air creates a plasma that radiates broadband electromagnetic waves. We experimentally compare the generation of microwaves from plasmas produced with two different laser systems that operate in the near- and mid-infrared regimes. Changing the laser wavelength inc...

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Veröffentlicht in:	Physical review. A 2021-07, Vol.104 (1), Article 013107
Hauptverfasser:	Englesbe, Alexander, Elle, Jennifer, Schwartz, Robert, Garrett, Travis, Woodbury, Daniel, Jang, Dogeun, Kim, Ki-Yong, Milchberg, Howard, Reid, Remington, Lucero, Adrian, Gordon, Daniel, Phillips, Ryan, Kalmykov, Serge, Schmitt-Sody, Andreas
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Schlagworte:	70 PLASMA PHYSICS AND FUSION TECHNOLOGY Atomic and molecular processes in external fields High intensity laser-plasma interactions Laser-plasma interactions Multiphoton or tunneling ionization and excitation Nonlinear optics Optics Optics and lasers Photorefractive and Kerr effects Physics Plasma diagnostic techniques Plasma interactions Radiation and particle generation in plasmas Radio-frequency and microwave plasma measurements Strong electromagnetic field effects Ultrashort pulses
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container_title	Physical review. A
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creator	Englesbe, Alexander Elle, Jennifer Schwartz, Robert Garrett, Travis Woodbury, Daniel Jang, Dogeun Kim, Ki-Yong Milchberg, Howard Reid, Remington Lucero, Adrian Gordon, Daniel Phillips, Ryan Kalmykov, Serge Schmitt-Sody, Andreas
description	An ultrashort laser pulse focused in air creates a plasma that radiates broadband electromagnetic waves. We experimentally compare the generation of microwaves from plasmas produced with two different laser systems that operate in the near- and mid-infrared regimes. Changing the laser wavelength increases the microwave power by 100 times and changing the input pulse energy allows for tuning of the microwave frequency spectrum, which we absolutely calibrate over a range of 2–70 GHz. The variation of the spectrum with laser pulse energy confirms the existence of a distinct mechanism that generates microwave radiation from laser-produced plasmas in gases. We propose that a radial diffusive expansion wave of the plasma electrons drives a longitudinal current along the plasma surface whose amplitude varies with the total residual electron energy imparted by the laser field and this longitudinal current produces the detected radiation.
doi_str_mv	10.1103/PhysRevA.104.013107
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subjects	70 PLASMA PHYSICS AND FUSION TECHNOLOGY Atomic and molecular processes in external fields High intensity laser-plasma interactions Laser-plasma interactions Multiphoton or tunneling ionization and excitation Nonlinear optics Optics Optics and lasers Photorefractive and Kerr effects Physics Plasma diagnostic techniques Plasma interactions Radiation and particle generation in plasmas Radio-frequency and microwave plasma measurements Strong electromagnetic field effects Ultrashort pulses
title	Ultrabroadband microwave radiation from near- and mid-infrared laser-produced plasmas in air
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