Suppression of Multiple Ionization of Atomic Ions in Intense Ultrafast Laser Pulses

Greenwood, J. B.; Johnston, I.M.G.; McKenna, P.; Williams, Ian D.; Goodworth, T. R. J.; Sanderson, Joseph; Bryan, William A.; El-Zein, A.A.A.; Newell, W R; Langley, A. J.; Divall, E. J.

doi:10.1103/physrevlett.88.233001

Cited by 15 publications

(3 citation statements)

References 33 publications

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“…The ease of the initial ionization is critical in determining the efficiency with which laser energy is absorbed and multiple ionization proceeds. Supporting evidence for this assertion comes from the only experiment to measure multiple ionization from a target which is initially positively charged (Greenwood et al 2002). In this study it was found that non-sequential ionization from Ar + was dramatically suppressed, when compared with neutral Ar.…”

Section: Introductionmentioning

confidence: 75%

Double ionization of atomic negative ions in an intense laser field

Greenwood

Collins

Pedregosa-Gutierrez

et al. 2003

J. Phys. B: At. Mol. Opt. Phys.

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In recent years there have been many studies of multiple ionization of closed shell rare gas atoms by intense laser fields. Until now no similar work has been done in the study of more diverse targets such as negative ions where low binding energies and strong electron correlations could yield distinctive behaviour. We present the first results of ionization of more than one electron from a range of atomic negative ions by intense laser pulses. Although these pulses are long by modern standards, and tend to produce sequential ionization in atoms, the positive ion yields from the negative ions do not depend predictably on the ionization potentials. This suggests that there may, intriguingly, be an alternative mechanism enhancing double ionization at low intensities.

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Section: Introductionmentioning

confidence: 75%

Double ionization of atomic negative ions in an intense laser field

Greenwood

Collins

Pedregosa-Gutierrez

et al. 2003

J. Phys. B: At. Mol. Opt. Phys.

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“…For example, studies have revealed that even in the case of atoms, subtle features of the ionization process may be masked by integration over the entire focal region [4,5]. Additionally, Greenwood et al applied the technique of "intensity selective scanning" to an Ar ϩ ion beam target which revealed for the first time strong field ionization of high lying target metastable levels in an Ar ϩ beam [9]. Due to the spatial selectivity achieved using the 0.5 mm pin hole, the various charge states of Xe detected had very different volumetric weightings than those achieved in the conventional mode.…”

mentioning

confidence: 99%

Volumetric intensity dependence on the formation of molecular and atomic ions within a high intensity laser focus

Robson

Ledingham

McKenna

et al. 2005

J. Am. Soc. Mass Spectrom.

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The mechanism of atomic and molecular ionization in intense, ultra-short laser fields is a subject which continues to receive considerable attention. An inherent difficulty with techniques involving the tight focus of a laser beam is the continuous distribution of intensities contained within the focus, which can vary over several orders of magnitude. The present study adopts time of flight mass spectrometry coupled with a high intensity (8 x 10(15) Wcm(-2)), ultra-short (20 fs) pulse laser in order to investigate the ionization and dissociation of the aromatic molecule benzene-d1 (C(6)H(5)D) as a function of intensity within a focused laser beam, by scanning the laser focus in the direction of propagation, while detecting ions produced only in a "thin" slice (400 and 800 microm) of the focus. The resultant TOF mass spectra varies significantly, highlighting the dependence on the range of specific intensities accessed and their volumetric weightings on the ionization/dissociation pathways accessed.

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“…Many surprises were found and models are revised continuously and range from a sequential ionization [4], i.e. 2+ comes from 1+ and 3+ via 2+, etc., to the tunneling ionization model and above threshold ionization, to a re-scattering model of the ionized electron that causes multiple ionization [5]. In these cases, the strong electrical field modulates the Coulomb potential and subsequent ionization processes are responsible for the degree of ionization [1].…”

Section: Introductionmentioning

confidence: 99%

Electromagnetically confined plasma target for interaction studies with intense laser fields

Schneider¹,

McDonald²,

Zielbauer³

et al. 2007

Nuclear Instruments and Methods in Physics Research Section B:

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The paper describes a novel application of an electron beam ion trap as a plasma target facility for intense laser-plasma interaction studies. The low density plasma target (~10 /cm3 ) is confined in a mobile cryogenic electromagnetic charged particle trap, with the magnetic confinement field of 1-3 T maintained by a superconducting magnet. Ion plasmas for a large variety of ion species and charge states are produced and maintained within the magnetic field and the space-charge of an energetic electron beam in the ''electron beam ion trap'' (EBIT) geometry. Intense laser beams (optical lasers, X-ray lasers and upcoming ''X-ray free electron lasers'' (XFEL)) provide strong time varying electromagnetic fields (>10 12 V/cm in femto-to nano-second pulses) for interactions with electromagnetically confined neutral/non-neutral plasmas. Experimental scenarios with intense photon fields on ionization/excitation processes, the ionization balance, as well as photon polarization effects and tests with intense lasers that utilize the ion plasma target are outlined. A first test of the plasma target with the PHELIX high intensity laser at GSI is described.

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Suppression of Multiple Ionization of Atomic Ions in Intense Ultrafast Laser Pulses

Cited by 15 publications

References 33 publications

Double ionization of atomic negative ions in an intense laser field

Double ionization of atomic negative ions in an intense laser field

Volumetric intensity dependence on the formation of molecular and atomic ions within a high intensity laser focus

Electromagnetically confined plasma target for interaction studies with intense laser fields

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