2019
DOI: 10.1103/physreve.99.062219
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Resonances between fundamental frequencies for lasers with large delayed feedbacks

Abstract: High-order frequency locking phenomena were recently observed using semiconductor lasers subject to large delayed feedbacks [1,2]. Specifically, the relaxation oscillation (RO) frequency and a harmonic of the feedback-loop round-trip frequency coincided with the ratios 1:5 to 1:11. By analyzing the rate equations for the dynamical degrees of freedom in a laser subject to a delayed optoelectronic feedback, we show that the onset of a two-frequency train of pulses occurs through two successive bifurcations. Whil… Show more

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Cited by 13 publications
(22 citation statements)
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“…The corresponding nonlinear structure looks like an empty cavity of pulse length with an electrostatic field filled with a laser field (a "laser bullet"). The considered relativistic laser pulse satisfies the condition of complete electron cavitation immediately at the entrance of the light into the target, which supports almost the same pulse radius over entire propagation length until pulse depletion in accordance with the most advanced theory, where self-focusing is associated with plasma nonlinearities due to both relativistic electron mass variation and relativistic charge displacement [20]. Acceleration of electrons in laser bullet occurs as a combination of direct laser acceleration and electrostatic wake acceleration with a stochastic feature.…”
Section: Discussionsupporting
confidence: 78%
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“…The corresponding nonlinear structure looks like an empty cavity of pulse length with an electrostatic field filled with a laser field (a "laser bullet"). The considered relativistic laser pulse satisfies the condition of complete electron cavitation immediately at the entrance of the light into the target, which supports almost the same pulse radius over entire propagation length until pulse depletion in accordance with the most advanced theory, where self-focusing is associated with plasma nonlinearities due to both relativistic electron mass variation and relativistic charge displacement [20]. Acceleration of electrons in laser bullet occurs as a combination of direct laser acceleration and electrostatic wake acceleration with a stochastic feature.…”
Section: Discussionsupporting
confidence: 78%
“…where self-focusing is associated with plasma nonlinearities due to both relativistic electron mass variation and relativistic charge displacement [20].…”
Section: Self-trapping Regimementioning
confidence: 99%
“…To understand condition (1) for stable relativistic self-channeling of a Gaussian laser beam entering a plasma, we use a commonly used model based on the nonlinear Schrödinger equation (NLSE) for the complex amplitude of the laser electric field [11]. Although this model is based on a simple stationary envelope treatment, it can shed light on the physics of the propagation of a short laser pulse.…”
Section: Self-trapping Regimementioning
confidence: 99%
“…The influence of both mechanisms on the propagation mode for a relativistic laser beam has been discussed in detail in various papers [14,[16][17][18][19] and monographs [20,21]. A recent work [11] gives an analytical description of a self-focusing structure formation for a laser beam having a given form of the radial intensity distribution at the plasma entrance which can be plasma-vacuum interface, as in our PIC model. This work which includes the mentioned relativistic nonlinearities has taken an important step towards the solution of the boundary-value problem for the incident Gaussian light beam, that is exactly what corresponds to PIC simulations with parameter R inside plasma.…”
Section: Self-trapping Regimementioning
confidence: 99%
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