XUV digital in-line holography using high-order harmonics

A. L’Huillier; A.-S. Morlens; C. Jacobsen; C.-G. Wahlström; D. Gabor; E. Georgiadou; E. Mengotti; E. Pourtal; F. Brizuela; G. Genoud; H.N. Chapman; I. McNulty; I.J. Kim; J. Garcia-Sucerquia; J. Mauritsson; J.P. Allebach; L. Déroff Le; O. Guilbaud; P. Zeitoun; R. Bartels; R.A. Bartels; R.I. Tobey; R.L. Sandberg; S. Eisebitt; S.-G. Pettersson; T. Pfeifer; U. Schnars; V. Ayvazyan; X. Deng; X.H. Huang

research

XUV digital in-line holography using high-order harmonics

Authors: A. L’Huillier
A.-S. Morlens
C. Jacobsen
C.-G. Wahlström
D. Gabor
E. Georgiadou
E. Mengotti
E. Pourtal
F. Brizuela
G. Genoud
H.N. Chapman
I. McNulty
I.J. Kim
J. Garcia-Sucerquia
J. Mauritsson
J.P. Allebach
L. Déroff Le
O. Guilbaud
P. Zeitoun
R. Bartels
R.A. Bartels
R.I. Tobey
R.L. Sandberg
S. Eisebitt
S.-G. Pettersson
T. Pfeifer
U. Schnars
V. Ayvazyan
X. Deng
X.H. Huang
Publication date: 27 September 2007
Publisher: 'Springer Science and Business Media LLC'
Doi

Abstract

A step towards a successful implementation of timeresolved digital in-line holography with extreme ultraviolet radiation is presented. Ultrashort XUV pulses are produced as high-order harmonics of a femtosecond laser and a Schwarzschild objective is used to focus harmonic radiation at 38 nm and to produce a strongly divergent reference beam for holographic recording. Experimental holograms of thin wires are recorded and the objects reconstructed. Descriptions of the simulation and reconstruction theory and algorithms are also given. Spatial resolution of few hundreds of nm is potentially achievable, and micrometer resolution range is demonstrated.Comment: 8 pages, 8 figure