Attosecond electron interferometry

A method to determine the dynamics of a bound wave packet excited by an attosecond pulse, while - for the first time - keeping track of its spectral content with high precision, is presented. The key idea is that coincident with the creation of the bound wave packet, a broad continuum wave packet is...

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Bibliographic Details
Main Authors: Mauritsson, J., Remetter, T., Swoboda, M., Klunder, K., L'Huillier, A., Schafer, K.J., Ghafur, O., Kelkensberg, F., Siu, W., Johnsson, P., Vrakking, M., Znakovskaya, I., Uphues, T., Zherebtsov, S., Kling, M.F., Lepine, F., Benedetti, E., Ferrari, F., Sansone, G., Nisoli, M.
Format: Conference Proceeding
Language:English
Subjects:
Bandwidth
Electrons
Energy resolution
Interference
Interferometry
Laser excitation
Optical pulses
Probes
Propagation delay
Spectroscopy
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Summary:A method to determine the dynamics of a bound wave packet excited by an attosecond pulse, while - for the first time - keeping track of its spectral content with high precision, is presented. The key idea is that coincident with the creation of the bound wave packet, a broad continuum wave packet is launched . This free wave packet serves as a reference when, after a variable delay, the bound wave packet is ionized by a 7 fs infrared laser pulse, locked in phase with the bound wave packet. The interference fringes observed in the photoelectron spectrum enable precise determination of the bound electron wave packet. As in Ramsey spectroscopy, the spectral precision is here set not by the bandwidth of the excitation pulse, but by the delay between the pump and probe pulses as well as the experimental energy resolution of the photoelectron spectrometer used.
DOI:10.1109/CLEOE-EQEC.2009.5196356