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Photoelectron energy peaks shift against the radiation pressure in strong-field ionization.

Kang LinSebastian EckartAlexander HartungDaniel TrabertKilian FehreJonas RistLothar Ph H SchmidtMarkus S SchöfflerTill JahnkeMaksim KunitskiReinhard Dörner
Published in: Science advances (2022)
The photoelectric effect describes the ejection of an electron upon absorption of one or several photons. The kinetic energy of this electron is determined by the photon energy reduced by the binding energy of the electron and, if strong laser fields are involved, by the ponderomotive potential in addition. It has therefore been widely taken for granted that for atoms and molecules, the photoelectron energy does not depend on the electron's emission direction, but theoretical studies have questioned this since 1990. Here, we provide experimental evidence that the energies of photoelectrons emitted against the light propagation direction are shifted toward higher values, while those electrons that are emitted along the light propagation direction are shifted to lower values. We attribute the energy shift to a nondipole contribution to the ponderomotive potential that is due to the interaction of the moving electrons with the incident photons.
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