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Precise and accurate measurements of strong-field photoionisation and a transferrable laser intensity calibration standard

Ionization of atoms and molecules in strong laser fields is a fundamental process in many fields of research, especially in the emerging field of attosecond science. So far, demonstrably accurate data have only been acquired for atomic hydrogen (H), a species that is accessible to few investigators. Here we present measurements of the ionization yield for argon, krypton, and xenon with percentlevel accuracy, calibrated using H, in a laser regime widely used in attosecond science. We derive a transferrable calibration standard for laser peak intensity, accurate to 1.3%, that is based on a simple reference curve. In addition, our measurements provide a much-needed benchmark for testing models of ionisation in noble-gas atoms, such as the widely employed single-active electron approximation.

preprint2016arXivOpen access
W. C. WallaceO. GhafurC. KhurmiSatya Sainadh U.J. E. CalvertD. E. LabanM. G. PullenK. BartschatA. N. Grum-GrzhimailoD. WellsH. M. QuineyX. M. TongI. V. LitvinyukR. T. SangD. Kielpinski
physics.atom-ph
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Open access15 authors1 topic
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W. C. WallaceO. GhafurC. KhurmiSatya Sainadh U.J. E. CalvertD. E. LabanM. G. PullenK. BartschatA. N. Grum-GrzhimailoD. WellsH. M. QuineyX. M. TongI. V. LitvinyukR. T. SangD. Kielpinski

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