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16 results on '"Szoeke, Abraham"'

1. Electron Cascades Produced by Photoelectrons in Diamond

Author

Ziaja, Beata, Szoeke, Abraham, and Hajdu, Janos

Subjects
Condensed Matter, High Energy Physics - Phenomenology
Abstract

Secondary electron cascades are responsible for significant ionizations in macroscopic samples during irradiation with X-rays. A quantitative analysis of these cascades is needed, e.g. for assessing damage in optical components at X-ray free-electron lasers, and for understanding damage in samples exposed to the beam. Here we present results from Monte Carlo simulations, showing the space-time evolution of secondary electron cascades in diamond. These cascades follow the impact of a single primary electron at energies between 0.5-12 keV, representing the usual range for photoelectrons. The calculations describe the secondary ionizations caused by these electrons, the three-dimensional evolution of the electron cloud, and monitor the equivalent instantaneous temperature of the free-electron gas as the system cools during expansion. The dissipation of the impact energy proceeds predominantly through the production of secondary electrons whose energies are comparable to the binding energies of the valence (40-50 eV) and the core electrons (300 eV) in accordance with experiments and the models of interactions. The electron cloud generated by a 12 keV electron is strongly anisotropic in the early phases of the cascade (t <= 1 fs). At later times, the sample is dominated by low energy electrons, and these are scattered more isotropically by atoms in the sample. The results show that the emission of secondary electrons approaches saturation within about 100 fs, following the primary impact. At an impact energy of 12 keV, the total number of electrons liberated in the sample is <= 400 at 1000 fs. The results provide an understanding of ionizations by photoelectrons, and extend earlier models on low-energy electron cascades (E=0.25 keV, [ziaja,ziaja2]) to the higher energy regime of the photoelectrons., Comment: 17 pages, latex, 10 figures

Published
2002
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2. Space-time evolution of electron cascades in diamond

Author

Ziaja, Beata, Szoeke, Abraham, van der Spoel, David, and Hajdu, Janos

Subjects
Condensed Matter, High Energy Physics - Phenomenology
Abstract

Here we describe model calculations to follow the spatio-temporal evolution of secondary electron cascades in diamond. The band structure of the insulator has been explicitly incorporated into the calculations as it affects ionizations from the valence band. A Monte-Carlo model was constructed to describe the path of electrons following the impact of a single electron of energy E 250 eV. The results show the evolution of the secondary electron cascades in terms of the number of electrons liberated, the spatial distribution of these electrons, and the energy distribution among the electrons as a function of time. The predicted ionization rates (5-13 electrons in 100 fs) lie within the limits given by experiments and phenomenological models. Calculation of the local electron density and the corresponding Debye length shows that the latter is systematically larger than the radius of the electron cloud. This means that the electron gas generated does not represent a plasma in a single impact cascade triggered by an electron of E 250 eV energy. This is important as it justifies the independent-electron approximation used in the model. At 1 fs, the (average) spatial distribution of secondary electrons is anisotropic with the electron cloud elongated in the direction of the primary impact. The maximal radius of the cascade is about 50 A at this time. As the system cools, energy is distributed more equally, and the spatial distribution of the electron cloud becomes isotropic. At 90 fs maximal radius is about 150 A. The Monte-Carlo model described here could be adopted for the investigation of radiation damage in other insulators and has implications for planned experiments with intense femtosecond X-ray sources., Comment: 26 pages, latex, 13 figures

Published
2002
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3. Shake-up and shake-off excitations with associated electron losses in X-ray studies of proteins

Author

Persson, Petter, Lunell, Sten, Szoeke, Abraham, Ziaja, Beata, and Hajdu, Janos

Subjects
Condensed Matter, High Energy Physics - Phenomenology, Quantitative Biology
Abstract

Photoionisation of an atom by X-rays usually removes an inner-shell electron from the atom, leaving behind a perturbed "hollow ion" whose relaxation may take different routes. In light elements, emission of an Auger electron is common. However, the energy and the total number of electrons released from the atom may be modulated by shake-up and shake-off effects. When the inner-shell electron leaves, the outer-shell electrons may find themselves in a state that is not an eigen-state of the atom in its surroundings. The resulting collective excitation is called shake-up. If this process also involves the release of low energy electrons from the outer shell, then the process is called shake-off. It is not clear how significant shake-up and shake-off contributions are to the overall ionisation of biological materials like proteins. In particular, the interaction between the out-going electron and the remaining system depends on the chemical environment of the atom, which can be studied by quantum chemical methods. Here we present calculations on model compounds to represent the most common chemical environments in proteins. The results show that the shake-up and shake-off processes affect about 20% of all emissions from nitrogen, 30% from carbon, 40% from oxygen, and 23% from sulphur. Triple and higher ionisations are rare for carbon, nitrogen and oxygen, but are frequent for sulphur. The findings are relevant to the design of biological experiments at emerging X-ray free-electron lasers., Comment: 14 pages, latex, 1 figure

Published
2001

4. Auger-electron cascades in diamond and amorphous carbon

Author

Ziaja, Beata, van der Spoel, David, Szoeke, Abraham, and Hajdu, Janos

Subjects
Condensed Matter, High Energy Physics - Phenomenology
Abstract

We have analyzed the cascade of secondary electrons in diamond and amorphous carbon generated by the thermalisation of a single Auger electron. The elastic electron mean free path was calculated as a function of impact energy in the muffin-tin potential approximation. The inelastic scattering cross section and the energy loss of the electron (expressed in terms of differential inverse mean free path) were estimated from two "optical" models, that utilise the measured dielectric constants of the materials. Using these data, a Monte-Carlo model describing the time evolution of the cascade was constructed. The results show that at most around 20-40 secondary cascade electrons are released by a single Auger electron in a macroscopic sample of diamond or amorphous carbon. Consideration of the real band structure of diamond reduces this number further. The release of the cascade electrons happens within the first 100 femtoseconds after the emission of the primary Auger electron. The results have implications to planned experiments with femtosecond X-ray sources., Comment: 18 pages, latex, 9 figures

Published
2001
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12. Massively parallel X-ray holography

Author

Marchesini, Stefano, Boutet, Sebastien, Sakdinawat, Anne E., Bogan, Michael J., Bajt, Sasa, Barty, Anton, Chapman, Henry N., Frank, Matthias, Hau-Riege, Stefan P., Szoeke, Abraham, Cui, Congwu, Shapiro, David A., Howells, Malcolm R., Spence, John C. H., Shaevitz, Joshua W., Lee, Joanna Y., Hajdu, Janos, Seibert, Marvin M., Marchesini, Stefano, Boutet, Sebastien, Sakdinawat, Anne E., Bogan, Michael J., Bajt, Sasa, Barty, Anton, Chapman, Henry N., Frank, Matthias, Hau-Riege, Stefan P., Szoeke, Abraham, Cui, Congwu, Shapiro, David A., Howells, Malcolm R., Spence, John C. H., Shaevitz, Joshua W., Lee, Joanna Y., Hajdu, Janos, and Seibert, Marvin M.

Abstract

Advances in the development of free-electron lasers offer the realistic prospect of nanoscale imaging on the timescale of atomic motions. We identify X-ray Fourier-transform holography(1,2,3) as a promising but, so far, inefficient scheme to do this. We show that a uniformly redundant array(4) placed next to the sample, multiplies the efficiency of X-ray Fourier transform holography by more than three orders of magnitude, approaching that of a perfect lens, and provides holographic images with both amplitude-and phase-contrast information. The experiments reported here demonstrate this concept by imaging a nano-fabricated object at a synchrotron source, and a bacterial cell with a soft-X-ray free-electron laser, where illumination by a single 15-fs pulse was successfully used in producing the holographic image. As X-ray lasers move to shorter wavelengths we expect to obtain higher spatial resolution ultrafast movies of transient states of matter.

Published
2008
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13. High-Intensity Photoionization of H sub 2

Author

LAWRENCE LIVERMORE NATIONAL LAB CA, Allendorf, Sarah W., Szoeke, Abraham, LAWRENCE LIVERMORE NATIONAL LAB CA, Allendorf, Sarah W., and Szoeke, Abraham

Abstract

A tunable, high-intensity picosecond dye laser system has been employed with electron energy analysis to investigate the dynamics of (3+1) resonance-enhanced multiphoton ionization of H2 via different vibrational levels of its electronic states. We observe production of molecular ions in various vibrational levels, with a shift to increased population of lower vibrational states of H2(+) consistent with the a.c. Stark shift of the correspondingly lower vibrational levels of the C state into resonance with the three-photon energy of the laser. Clear evidence of direct dissociation of H2 followed by single-photon ionization of the excited H atom is observed as well. Above threshold ionization of these two processes occurs readily. We also find that dissociative ionization is an increasingly important ionization pathway, which we assign to photoionization into a transient bound state created by the avoided crossing of the first repulsive electronic state of H2(+), with the single-photon dressed ground state of H2(+)., This article is from 'Osa Proceedings of the Topical Meeting (5th) on Short-Wave Length Coherent Radiation: Generation and Applications Held in Monterey, California o 8-10 April 1991. Volume 11,' AD-A252 973, p227-231.

Published
1992

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