Breakdown of the isotropic asymptotic approximation in two-colour photoionisation

Sooraj Rajendran; Miguel Benito de Lama; Praveen Kumar Maroju; Michele Di Fraia; Oksana Plekan; David Busto; Ioannis Makos; Marvin Schmoll; Luca Giannessi; Enrico Allaria; Primo\v{z} Rebernik Ribi\v{c}; Giovanni De Ninno; Alexander Demidovich; Miltcho Danailov; Marco Zangrando; Kenneth J. Schafer; Richard J. Squibb; Raimund Feifel; Tam\'as Csizmadia; Fabio Frassetto; Luca Poletto; Kevin C. Prince; Johan Mauritsson; Carlo Callegari; Johannes Feist; Alicia Palacios; Giuseppe Sansone

arXiv:2603.15293·physics.atom-ph·March 17, 2026

Breakdown of the isotropic asymptotic approximation in two-colour photoionisation

Sooraj Rajendran, Miguel Benito de Lama, Praveen Kumar Maroju, Michele Di Fraia, Oksana Plekan, David Busto, Ioannis Makos, Marvin Schmoll, Luca Giannessi, Enrico Allaria, Primo\v{z} Rebernik Ribi\v{c}, Giovanni De Ninno, Alexander Demidovich, Miltcho Danailov, Marco Zangrando

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TL;DR

This paper investigates the limitations of the asymptotic approximation used to isolate the Wigner delay in two-colour photoionisation, revealing its breakdown through experimental and simulation evidence.

Contribution

It introduces a self-referencing method using non-consecutive EUV harmonics to test the validity of the asymptotic approximation in attosecond photoionisation.

Findings

01

Observed deviations of a few tens of milliradians from the approximation.

02

Experimental results agree with full-dimensional simulations.

03

Demonstrated the breakdown of the asymptotic approximation.

Abstract

The Wigner delay is defined as the energy derivative of the scattering phase of a particle in a given potential, unveiling the time taken (or gained) due to the interaction. The characterisation of this delay plays a central role in attosecond science, where the time resolution allows to gain information on the time interval required for a photoelectron to be emitted into the continuum after the absorption of a single photon. Attosecond interferometric techniques, based on two-colour (extreme ultraviolet and near-infrared) photoionisation schemes, cannot provide a direct measurement of the Wigner delay, because the low-frequency photon contributes with an additional delay, which is imprinted on the outgoing photoelectron. The isolation of the Wigner delay is usually achieved by appealing to the asymptotic approximation, which assumes that the two-photon delay is separable into a Wigner…

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Taxonomy

TopicsLaser-Matter Interactions and Applications · Spectroscopy and Quantum Chemical Studies · Quantum Mechanics and Applications