Strong laser fields were supposed to be the cleanest way to watch electrons move, yet the latest experiments show that the vacuum itself can quietly reshape what those fields do. By flooding matter ...

A team of researchers has successfully demonstrated nonlinear Compton scattering (NCS) between an ultra-relativistic electron beam and an ultrahigh intensity laser pulse using the 4-Petawatt laser.

Strong field laser physics investigates the interaction between intense laser pulses and matter, a domain where non-linear phenomena such as multiphoton absorption, tunnelling ionisation, and ...

Ionization is crucial in strong field physics and attosecond science, where it describes how electrons escape from their ...

A team of researchers from the University of Ottawa has made significant strides in understanding the ionization of atoms and molecules, a fundamental process in physics that has implications for ...

Figure 1. Correlated spectrum of angular momentum and energy (SAME) at the tunnel exit for photoelectrons originating from ionization of the helium atom exposed to (1) circularly or (2) elliptically ...

A typical 3D configuration in the superconducting vortex phase in the (hyper)magnetic field background of about 150 exatesla. The equipotential surfaces of the superconducting W condensate are shown ...

Adapting a detector developed for space X-ray observation, researchers have successfully verify strong-field quantum electrodynamics with exotic atoms. An international collaboration of researchers, ...

Physicists Prof. Dr. Ingo Rehberg from the University of Bayreuth and Dr. Peter Blümler from Johannes Gutenberg University Mainz have developed and experimentally validated an innovative approach for ...

Strong-field laser physics investigates the interaction between intense laser fields and matter, revealing complex ionization dynamics that extend far beyond traditional perturbative regimes. At these ...