Controlling X-rays with light

Ultrafast X-ray science is an exciting frontier that promises the visualization of electronic, atomic and molecular dynamics on atomic time and length scales. A largely unexplored area of ultrafast X-ray science is the use of light to control how X-rays interact with matter. To extend control concep...

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Veröffentlicht in:	Nature Phys 2010-01, Vol.6 (1), p.69-74
Hauptverfasser:	Young, L, Glover, T. E, Hertlein, M. P, Southworth, S. H, Allison, T. K, van Tilborg, J, Kanter, E. P, Krässig, B, Varma, H. R, Rude, B, Santra, R, Belkacem, A
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Schlagworte:	ABSORPTION Atomic Classical and Continuum Physics CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS Complex Systems Condensed Matter Physics Electronics Light LIGHT SOURCES Mathematical and Computational Physics Molecular Optical and Plasma Physics Optics Physics Physics and Astronomy PROBES Theoretical Transparency X-RAY SOURCES X-rays
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creator	Young, L Glover, T. E Hertlein, M. P Southworth, S. H Allison, T. K van Tilborg, J Kanter, E. P Krässig, B Varma, H. R Rude, B Santra, R Belkacem, A
description	Ultrafast X-ray science is an exciting frontier that promises the visualization of electronic, atomic and molecular dynamics on atomic time and length scales. A largely unexplored area of ultrafast X-ray science is the use of light to control how X-rays interact with matter. To extend control concepts established for long-wavelength probes to the X-ray regime, the optical control field must drive a coherent electronic response on a timescale comparable to femtosecond core-hole lifetimes. An intense field is required to achieve this rapid response. Here, an intense optical control pulse is observed to efficiently modulate photoelectric absorption for X-rays and to create an ultrafast transparency window. We demonstrate an application of X-ray transparency relevant to ultrafast X-ray sources: an all-photonic temporal cross-correlation measurement of a femtosecond X-ray pulse. The ability to control X-ray–matter interactions with light will create new opportunities for present and next-generation X-ray light sources. Intense optical beams can alter the way that a material interacts with X-ray radiation. This is now demonstrated by experiments that use femtosecond laser pulses to affect inner-shell processes in neon atoms, increasing the transmission of X-rays. This could allow imprinting of optical pulse trains onto much longer X-ray pulses.
doi_str_mv	10.1038/nphys1430
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E ; Hertlein, M. P ; Southworth, S. H ; Allison, T. K ; van Tilborg, J ; Kanter, E. P ; Krässig, B ; Varma, H. R ; Rude, B ; Santra, R ; Belkacem, A</creator><creatorcontrib>Young, L ; Glover, T. E ; Hertlein, M. P ; Southworth, S. H ; Allison, T. K ; van Tilborg, J ; Kanter, E. P ; Krässig, B ; Varma, H. R ; Rude, B ; Santra, R ; Belkacem, A ; Argonne National Lab. (ANL), Argonne, IL (United States)</creatorcontrib><description>Ultrafast X-ray science is an exciting frontier that promises the visualization of electronic, atomic and molecular dynamics on atomic time and length scales. A largely unexplored area of ultrafast X-ray science is the use of light to control how X-rays interact with matter. To extend control concepts established for long-wavelength probes to the X-ray regime, the optical control field must drive a coherent electronic response on a timescale comparable to femtosecond core-hole lifetimes. An intense field is required to achieve this rapid response. Here, an intense optical control pulse is observed to efficiently modulate photoelectric absorption for X-rays and to create an ultrafast transparency window. We demonstrate an application of X-ray transparency relevant to ultrafast X-ray sources: an all-photonic temporal cross-correlation measurement of a femtosecond X-ray pulse. The ability to control X-ray–matter interactions with light will create new opportunities for present and next-generation X-ray light sources. Intense optical beams can alter the way that a material interacts with X-ray radiation. This is now demonstrated by experiments that use femtosecond laser pulses to affect inner-shell processes in neon atoms, increasing the transmission of X-rays. 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subjects	ABSORPTION Atomic Classical and Continuum Physics CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS Complex Systems Condensed Matter Physics Electronics Light LIGHT SOURCES Mathematical and Computational Physics Molecular Optical and Plasma Physics Optics Physics Physics and Astronomy PROBES Theoretical Transparency X-RAY SOURCES X-rays
title	Controlling X-rays with light
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