The Attosecond Revolution

The most intuitive way to understand the extreme nonlinear interaction that leads to attosecond pulses is through the semi-classical re-collision model. A strong infrared light pulse illuminating an atom or molecule creates a "free" electron wave packet by multiphoton ionization, usually approximated by tunneling. Tunneling occurs over a range of phases of the fundamental pulse near each crest of the laser electric field - a time window of roughly 300 attoseconds (as). In practice, in the infrared, multiphoton ionization intensities in the range of 10¹⁴ to 10¹⁵ W/cm² are needed, corresponding to peak electric field strengths of 3-10 V/Å...

This article by Paul Corkum and Zenghu Chang was the cover story in the October Optics & Photonics News. It is available in Acrobat form.

Recently Published Papers:

Elusive enhanced ionization structure for H₂⁺ in intense ultrashort laser pulses
I. Ben-Itzhak, et al
Phys. Rev. A 78, 063419 (2008)
Strong-field modulated diffraction effects in the correlated electron-nuclear motion in dissociating H₂⁺
Feng He, Andreas Becker, Uwe Thumm
Phys. Rev. Lett. 101, 213002 (2008)
See press release...

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This Week at JRM

Week of 04 Jan 2009

Mon	1:30 pm	Nuts & Bolts
Reports
Tue
Wed	1:30 pm	No AMO Seminar
Thu
Fri

Chang is APS Fellow

Congratulations to Zenghu Chang, our latest faculty member to become a Fellow of the APS.

"For contributions to the development of femtosecond x-ray streak cameras, to the stabilization of the carrier envelope phase of high power lasers, and to the generation of high order harmonics and attosecond pulses".