Litcius/Paper detail

Nonlinear spatiotemporal control of laser intensity

Tanner T. Simpson, Dillon Ramsey, Philip Franke, Navid Vafaei-Najafabadi, David Turnbull, Dustin H. Froula, John P. Palastro

2020Optics Express28 citationsDOIOpen Access PDF

Abstract

Spatiotemporal control over the intensity of a laser pulse has the potential to enable or revolutionize a wide range of laser-based applications that currently suffer from the poor flexibility offered by conventional optics. Specifically, these optics limit the region of high intensity to the Rayleigh range and provide little to no control over the trajectory of the peak intensity. Here, we introduce a nonlinear technique for spatiotemporal control, the "self-flying focus," that produces an arbitrary trajectory intensity peak that can be sustained for distances comparable to the focal length. The technique combines temporal pulse shaping and the inherent nonlinearity of a medium to customize the time and location at which each temporal slice within the pulse comes to its focus. As an example of its utility, simulations show that the self-flying focus can form a highly uniform, meter-scale plasma suitable for advanced plasma-based accelerators.

Topics & Concepts

OpticsTrajectoryNonlinear systemLaserIntensity (physics)PhysicsPulse (music)Focus (optics)Pulse shapingRange (aeronautics)Light intensityTracking (education)Flexibility (engineering)Nonlinear opticsLimit (mathematics)Computer scienceRayleigh scatteringRadiant intensityUltrashort pulseSelf-phase modulationPhysical opticsDynamic rangeIntensity modulationSpatial frequencyGeometrical opticsSpatial filterLaser-Plasma Interactions and DiagnosticsLaser-Matter Interactions and ApplicationsOrbital Angular Momentum in Optics