Litcius/Paper detail

Observation of the Relativistic Reversal of the Ponderomotive Potential

Jeremy J. Axelrod, Sara Campbell, Osip Schwartz, Carter Turnbaugh, Robert M. Glaeser, Holger Müller

2020Physical Review Letters32 citationsDOIOpen Access PDF

Abstract

The secular dynamics of a nonrelativistic charged particle in an electromagnetic wave can be described by the ponderomotive potential. Although ponderomotive electron-laser interactions at relativistic velocities are important for emerging technologies from laser-based particle accelerators to laser-enhanced electron microscopy, the effects of special relativity on the interaction have only been studied theoretically. Here, we use a transmission electron microscope to measure the position-dependent phase shift imparted to a relativistic electron wave function when it traverses a standing laser wave. The kinetic energy of the electrons is varied between 80 and 300 keV, and the laser standing wave has a continuous-wave intensity of 175 GW/cm^{2}. In contrast to the nonrelativistic case, we demonstrate that the phase shift depends on both the electron velocity and the wave polarization, confirming the predictions of a quasiclassical theory of the interaction. Remarkably, if the electron's speed is greater than 1/sqrt[2] of the speed of light, the phase shift at the electric field nodes of the wave can exceed that at the antinodes. In this case there exists a polarization such that the phase shifts at the nodes and antinodes are equal, and the electron does not experience Kapitza-Dirac diffraction. Our results thus provide new capabilities for coherent electron beam manipulation.

Topics & Concepts

PhysicsRelativistic quantum chemistryQuantum electrodynamicsNuclear physicsAtomic physicsLaser-Plasma Interactions and DiagnosticsParticle Accelerators and Free-Electron LasersAstrophysical Phenomena and Observations