XFEL experiments: jitter of pump-probe time delays and pulse intensities.

Jitter of XFEL signals due to fluctuations in shot-to-shot time delays and intensities are explored in the frame of a statistical theory of X-ray diffraction from liquids. Deformed signals are calculated at different levels of pump-probe jitter. A new method is proposed to eliminate these distortions.

Liquid X-ray scattering with a pink-spectrum undulator.

X-ray scattering from a liquid using the spectrum from the undulator fundamental is examined as a function of the bandwidth of the spectrum. The synchrotron-generated X-ray spectrum from an undulator is 'pink', i.e.

Filming the birth of molecules and accompanying solvent rearrangement.

Molecules are often born with high energy and large-amplitude vibrations. In solution, a newly formed molecule cools down by transferring energy to the surrounding solvent molecules. The progression of the molecular and solute-solvent cage structure during this fundamental process has been elusive, and spectroscopic data generally do not provide such structural information.

Filming atomic motions in liquids.

Basic techniques in ultrafast time-resolved optical spectroscopy and x-ray diffraction are described for a broad scientific community. Basic experimental setups are presented, and theories for the interpretation of experimental data are briefly described. The power of these ultrafast techniques is shown with a few selected examples.

Time-resolved observation of the Eigen cation in liquid water.

Experimental observation and time relaxation measurement of the hydrated proton Eigen form [H(3)O(+)(H(2)O)(3)] are presented here. Vibrational time-resolved spectroscopy is used with an original method of investigating the proton excess in water. The anharmonicity of the time-resolved spectra is characteristic of the Eigen-type proton geometry.