Abstract
In this work we present a reflective split-and-delay unit (SDU) developed for interferometric time-resolved experiments utilizing an (extreme ultraviolet) XUV pump–XUV probe scheme with focused free-electron laser beams. The developed SDU overcomes limitations for phase-resolved measurements inherent to conventional two-element split mirrors by a special design using two reflective lamellar gratings. The gratings produce a high-contrast interference signal controlled by the grating displacement in every diffraction order. The orders are separated in the focal plane of the focusing optics, which enables one to avoid phase averaging by spatially selective detection of a single interference state of the two light fields. Interferometry requires a precise relative phase control of the light fields, which presents a challenge at short wavelengths. In our setup the phase delay is determined by an in-vacuum white light interferometer (WLI) that monitors the surface profile of the SDU in real time and thus measures the delay for each laser shot. The precision of the WLI is 1 nm as determined by optical laser interferometry. In the presented experimental geometry it corresponds to a time delay accuracy of 3 as, which enables phase-resolved XUV pump–XUV probe experiments at free-electron laser (FEL) repetition rates up to 60 Hz.
Highlights
The recent fast development of table-top high harmonic generation (HHG) [1,2] and free-electron laser (FEL) light sources [3,4,5] made short and intense light pulses available in the extreme ultraviolet (XUV) and soft X-ray wavelength ranges
Using the the white light interferometer (WLI), WLI, we we found found that that the the movable movable grating grating is is affected affected by by environmental environmental vibrations vibrations transmitted to the experimental chamber
The split-and-delay unit (SDU) consists of two interleaved lamellar gratings
Summary
The recent fast development of table-top high harmonic generation (HHG) [1,2] and free-electron laser (FEL) light sources [3,4,5] made short and intense light pulses available in the extreme ultraviolet (XUV) and soft X-ray wavelength ranges. This opens new opportunities for ultrafast science, in particular new time-resolved studies. The simplest interferometric experiment requires two phase-locked light fields.
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