Add to ORKGHelium atoms in the presence of extreme ultraviolet light pulses can lose electrons through direct photoionization or through two-electron excitation followed by autoionization. Here we demonstrate that, by combining attosecond extreme ultraviolet pulses with near infrared femtosecond lasers, electron dynamics in helium autoionization can be not only monitored but also controlled. Furthermore, the interference between the two ionization channels was modified by the intense near infrared laser pulse. To the best of our knowledge, this is the first time that double excitation and autoionization were studied experimentally by using isolated attosecond pulses. © 2010 The American Physical Society
A train of attosecond pulses, synchronized to an infrared (IR) laser field, is used to create a seri...
We present experiments, supported by time-dependent Schrödinger simulations, on the dynamics of Heli...
Attosecond electron wavepackets are produced when an intense laser field ionizes an atom or a molecu...
Helium atoms in the presence of extreme ultraviolet light pulses can lose electrons through direct p...
Electron dynamics in atoms and molecules occurs on a time-scale of attoseconds (10⁻¹⁸s). With the av...
Attosecond control of the optical response of helium atoms to extreme ultraviolet radiation in the p...
When small quantum systems, atoms or molecules, absorb a high-energy photon, electrons are emitted w...
Contains fulltext : 110236.pdf (publisher's version ) (Open Access)Using high-orde...
Within this work, electron dynamics in atoms are experimentally and numerically investigated on thei...
© 2015 American Physical Society. We derive an analytical solution uncovering the origin of few-cycl...
We propose a general technique to retrieve the information of dipole-forbidden resonances in the aut...
Recent advances in laser technology have led to the generation of attosecond laser pulses, whose dur...
Using high-order harmonic attosecond pulse trains, we investigate the photoionization dynamics and t...
We study two-photon double ionization of helium. We demonstrate that attosecond pulses can be used t...
Attosecond electron wavepackets are produced when an intense laser field ionizes an atom or a molecu...
A train of attosecond pulses, synchronized to an infrared (IR) laser field, is used to create a seri...
We present experiments, supported by time-dependent Schrödinger simulations, on the dynamics of Heli...
Attosecond electron wavepackets are produced when an intense laser field ionizes an atom or a molecu...
Helium atoms in the presence of extreme ultraviolet light pulses can lose electrons through direct p...
Electron dynamics in atoms and molecules occurs on a time-scale of attoseconds (10⁻¹⁸s). With the av...
Attosecond control of the optical response of helium atoms to extreme ultraviolet radiation in the p...
When small quantum systems, atoms or molecules, absorb a high-energy photon, electrons are emitted w...
Contains fulltext : 110236.pdf (publisher's version ) (Open Access)Using high-orde...
Within this work, electron dynamics in atoms are experimentally and numerically investigated on thei...
© 2015 American Physical Society. We derive an analytical solution uncovering the origin of few-cycl...
We propose a general technique to retrieve the information of dipole-forbidden resonances in the aut...
Recent advances in laser technology have led to the generation of attosecond laser pulses, whose dur...
Using high-order harmonic attosecond pulse trains, we investigate the photoionization dynamics and t...
We study two-photon double ionization of helium. We demonstrate that attosecond pulses can be used t...
Attosecond electron wavepackets are produced when an intense laser field ionizes an atom or a molecu...
A train of attosecond pulses, synchronized to an infrared (IR) laser field, is used to create a seri...
We present experiments, supported by time-dependent Schrödinger simulations, on the dynamics of Heli...
Attosecond electron wavepackets are produced when an intense laser field ionizes an atom or a molecu...