Abstract-All-optical attoclock: accessing exahertz dynamics of optical tunnelling through terahertz emission

I. Babushkin, A. J. Galan, A. Husakou, F. Morales, A. Demircan, J. R. C. Andrade, U. Morgner, M. Ivanov

https://arxiv.org/abs/1803.04187

The hot debate regarding attosecond dynamics of optical tunneling has, so far, been focused on the presence, or absence, of time delays associated to the electron tunnelling through the classically forbidden region during atomic ionization in intense infrared laser fields. Strong theoretical and experimental arguments have been put forward to advocate the polar opposite points of view. The underlying dynamics are richer. Here we propose to use the nonlinear optical responses of the tunnelling electrons to tailored light fields to track these dynamics in full complexity. Using the combination of single-color and two-color fields, we resolve not only ionization delays, but also temporal re-shaping and spatial re-focusing of the tunnelling wavepacket as it emerges from the classically forbidden region. Access to these details of the dynamics is facilitated by the near-instantaneous nature of the nonlinear optical response driven by ionization, and by using tailored laser pulses to induce this response. Our work introduces a new type of attoclock for optical tunnelling, one that is based on measuring light rather than photo-electrons. Our conclusions suggest a possible middle ground between the two conflicting points of view.

Abstract-Symmetry Breaking and Strong Persistent Plasma Currents via Resonant Destabilization of Atoms

C. Brée, M. Hofmann, A. Demircan, U. Morgner, O. Kosareva, A. Savel’ev, A. Husakou, M. Ivanov, and I. Babushkin

https://journals.aps.org/prl/abstract/10.1103/PhysRevLett.119.243202

The ionization rate of an atom in a strong optical field can be resonantly enhanced by the presence of long-living atomic levels (so-called Freeman resonances). This process is most prominent in the multiphoton ionization regime, meaning that the ionization event takes many optical cycles. Nevertheless, here, we show that these resonances can lead to rapid subcycle-scale plasma buildup at the resonant values of the intensity in the pump pulse. The fast buildup can break the cycle-to-cycle symmetry of the ionization process, resulting in the generation of persistent macroscopic plasma currents which remain after the end of the pulse. This, in turn, gives rise to a broadband radiation of unusual spectral structure, forming a comb from terahertz to visible. This radiation contains fingerprints of the attosecond electron dynamics in Rydberg states during ionization.

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Abstract-Boosting Terahertz Generation in Laser-Field Ionized Gases Using a Sawtooth Wave Shape

P. González de Alaiza Martínez, I. Babushkin, L. Bergé, S. Skupin, E. Cabrera-Granado, C. Köhler, U. Morgner, A. Husakou, and J. Herrmann

Phys. Rev. Lett. 114, 183901 – Published 6 May 2015

http://journals.aps.org/prl/abstract/10.1103/PhysRevLett.114.183901

Broadband ultrashort terahertz (THz) pulses can be produced using plasma generation in a noble gas ionized by femtosecond two-color pulses. Here we demonstrate that, by using multiple-frequency laser pulses, one can obtain a waveform which optimizes the free electron trajectories in such a way that they acquire the largest drift velocity. This allows us to increase the THz conversion efficiency to 2%, an unprecedented performance for THz generation in gases. In addition to the analytical study of THz generation using a local current model, we perform comprehensive 3D simulations accounting for propagation effects which confirm this prediction. Our results show that THz conversion via tunnel ionization can be greatly improved with well-designed multicolor pulses.

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Abstract-Boosting terahertz generation in laser-field ionized gases using a sawtooth wave shape

P. González de Alaiza Martínez, I. Babushkin, L. Bergé, S. Skupin, E. Cabrera-Granado, C. Köhler, U. Morgner, A. Husakou, J. Herrmann

(Submitted on 16 Dec 2014)

http://arxiv-web3.library.cornell.edu/abs/1412.4995

Broadband ultrashort terahertz (THz) pulses can be produced using plasma generation in a noble gas ionized by femtosecond two-color pulses. Here we demonstrate that, by using multiple-frequency laser pulses, one can obtain a waveform which optimizes the free electron trajectories in such a way that they reach the highest velocity at the electric field extrema. This allows to increase the THz conversion efficiency to the percent level, an unprecedented performance for THz generation in gases. Besides the analytical study of THz generation using a local current model, we perform comprehensive 3D simulations accounting for propagation effects which confirm this prediction. Our results show that THz conversion via tunnel ionization can be greatly improved with well-designed multicolor pulses.