Nonlinear relativistic single-electron Thomson scattering power spectrum for incoming laser of arbitrary intensity

Alvarez‐Estrada, R. F.; Pastor, I.; Guasp, J.; Castejón, F.

doi:10.1063/1.4725190

Cited by 8 publications

(30 citation statements)

References 16 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In this section the mathematical formalism used to compare both phenomena in the frequency-domain is presented; it will provide the basis for the comparison in the time-domain in section 3. The steps to be taken closely follow the results for TS in [24][25][26][27]. Excellent monographs on classical electrodynamics and SR exist, which have been instrumental at the starting level of the present research: see, for example, [29,30,35,36].…”

Section: Towards the Tsc-hsr Similarity: Frequency-domain Analytical mentioning

confidence: 94%

“…x x x x = + + ( ) ( )ˆ( )ˆ( )ˆis the solution of the dynamical equations of motion for the incoming circularly polarized monochromatic plane wave and t x c 3 x x = ¢ -( ) , t′ being the 'radiation' time for the electron; p(ξ) is the momentum of the radiating electron, also following from those dynamical equations [24,25]. x 1 (ξ), x 2 (ξ), x 3 (ξ) and p(ξ) are collected in appendix C. The quantities γ 1 , f 1 and f 2 , employed below, are integration constants of the dynamical equations of motion [24,25]. Λ (ξ) C can be recast as:…”

Section: Frequency-domain Radiated Fields At Detector Position For Hsrmentioning

confidence: 99%

“…Notice that ω 0 ξ is dimensionless and that we have approximated exp[iω((R/c)+(g 0,C /ω 0 ))];exp[iω(R/c)] in the quadratures given in equations (25) and (26),…”

Section: Frequency-domain Radiated Fields At Detector Position For Hsrmentioning

confidence: 99%

“…To the best of our knowledge, no attempt has been made to probe fusion plasmas with ultra-intense circularly polarised lasers, either with diagnostic purposes, or to obtain from them a light source with the special properties predicted from the nonlinear effects. Numerical work presented by the authors in [24,25,27] suggest that using an ultra-intense laser could shift the emitted spectrum to the red, and hence spectral zones that are normally unaccessible due to practical considerations, like the one around the laser wavelength, could now be directly observed, increasing the diagnostic capability. The predicted harmonics to the (bulk) scattered spectrum would also be of potential diagnostic use.…”

Section: Physical Applications Suggested By the Relationship Between mentioning

confidence: 99%

“…In previous papers the authors have developed Monte Carlo and analytical methods for the ab-initio computation (in a classical framework, disregarding quantum effects) of TS spectra under very general conditions regarding the electron distribution function, as well as the intensity and the polarization of the incoming laser radiation, for plasma fusion diagnostic applications [24][25][26][27][28]. In the course of these investigations,…”

Section: Introductionmentioning

confidence: 99%

See 4 more Smart Citations

On the similarity between Thomson scattering from high-intensity circularly polarised lasers and synchrotron radiation

et al. 2018

View full text Add to dashboard Cite

The mathematical similarity between Thomson Scattering (TS) and Synchrotron Radiation (SR) phenomena is elucidated, and some physical consequences are extracted from it. Analytical computations are reported in the frequency-and the time-domains so as to make this relationship more compelling. Algebraic equations for the relevant parameters implementing that similarity are obtained in the time-domain in their final form. Subsequently, those algebraic equations are numerically solved so as to make the connection available for a wide range of parameters in both phenomena. Prospects for a compact vacuum ultraviolet (VUV) or even x-ray source based on this analogy and using the interaction of high-intensity circularly polarized laser radiation with essentially monoenergetic electron beams are discussed. the close similarity of the temporal behaviour of radiated fields coming from TS from a circularly polarized laser (TSC) and Synchrotron Radiation (SR) has emerged. The present paper is devoted to a detailed investigation of this relationship.The similarity to be investigated below employs features of the SR phenomenon that are not quite common in modern laboratory applications of this effect, namely, out-of-the-orbital plane radiated fields in general and, perhaps more important, electron energies ranging from hundreds of keV up to some tens of MeV have to be used. This is to be compared with modern SR facilities, where energies in excess of several GeV are now standard. Also, the mathematical treatment of the SR below has included the presence of a component of the velocity/ momentum along the direction of the externally applied magnetic field (B 0 ), so that the general trajectory of the charged particle is a helix with axis parallel to B 0 , hence we shall refer to it as Helical Synchrotron Radiation (HSR). Various physical features of SR are well documented in the scientific literature (including in some cases helical trajectories): see [29][30][31][32], among others.The nonlinear interaction studies of ultra-intense lasers with energetic electrons have experienced a rapid increase over the last decade, driven by the availability of the former ones, which are now much more accesible and less bulky than a few years ago. In this connection, [33,34] represent two recent experimental milestones in this area of research, which are relevant for the problems dealt with in this paper, in particular [34], where very high order harmonics of the laser radiation are experimentally produced and studied. In these publications a more or less close connection between TS and SR is mentioned, without entering into a detailed comparison. Both phenomena deal with radiation from accelerated charges at relativistic energies, a major reason for the similarities. What is new in the present work (to the best of our knowledge) is the statement that if TS is performed with circularly polarized lasers, then, under some suitable conditions, the radiated fields for TSC and HSR in the time-domain have exactly the same form. Practical consequenc...

show abstract

Section: Towards the Tsc-hsr Similarity: Frequency-domain Analytical mentioning

confidence: 94%

Section: Frequency-domain Radiated Fields At Detector Position For Hsrmentioning

confidence: 99%

“…Notice that ω 0 ξ is dimensionless and that we have approximated exp[iω((R/c)+(g 0,C /ω 0 ))];exp[iω(R/c)] in the quadratures given in equations (25) and (26),…”

Section: Frequency-domain Radiated Fields At Detector Position For Hsrmentioning

confidence: 99%

Section: Physical Applications Suggested By the Relationship Between mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

On the similarity between Thomson scattering from high-intensity circularly polarised lasers and synchrotron radiation

et al. 2018

View full text Add to dashboard Cite

show abstract

Even-order harmonic generation from nonlinear Thomson backscatter in a tightly focused Gaussian laser pulse

Hong

Wei

et al. 2022

Physics of Plasmas

View full text Add to dashboard Cite

The electron dynamics and the Thomson backscattering spectra for an electron accelerating in a tightly focused Gaussian laser pulse are first investigated in detail. It is found that for a tightly focused Gaussian laser pulse, the ponderomotive force introduced due to the non-uniform intensity distribution of the laser pulse has the tendency to push out the electron from the laser pulse, which leads to the trajectory symmetry-breaking of the electron and then the generation of the even-order harmonics at the same time. Further, for the tightly focused Gaussian laser pulse, changes in several laser parameters, such as the increase of the laser peak amplitude, lengthening of the pulse width, and decrease of the beam waist, lead earlier to the relative ejected position of the electron to the laser pulse, which causes the more obvious trajectory symmetry-breaking of the electron, and then the more intensive peak intensity of the even-order harmonics. It is different from the well-known results of the plane waves and the Gaussian laser pulse with uniform transverse intensity distribution and provides a possible way for the generation of the even-order harmonics in nonlinear Thomson backscattering.

show abstract

A New Numerical Technique for the Inverse Problem in Thomson Scattering and Its Application to Experimental and Synthetic Spectra

Guasp

Castejón

Pastor

et al. 2017

Fusion Science and Technology

View full text Add to dashboard Cite

Nonlinear relativistic single-electron Thomson scattering power spectrum for incoming laser of arbitrary intensity

Cited by 8 publications

References 16 publications

On the similarity between Thomson scattering from high-intensity circularly polarised lasers and synchrotron radiation

On the similarity between Thomson scattering from high-intensity circularly polarised lasers and synchrotron radiation

Even-order harmonic generation from nonlinear Thomson backscatter in a tightly focused Gaussian laser pulse

A New Numerical Technique for the Inverse Problem in Thomson Scattering and Its Application to Experimental and Synthetic Spectra

Contact Info

Product

Resources

About