Measuring the frequency chirp of extreme-ultraviolet free-electron laser pulses by transient absorption spectroscopy

High-intensity ultrashort pulses at extreme ultraviolet (XUV) and x-ray photon energies, delivered by state-of-the-art free-electron lasers (FELs), are revolutionizing the field of ultrafast spectroscopy. For crossing the next frontiers of research, precise, reliable and practical photonic tools for the spectro-temporal characterization of the pulses are becoming steadily more important. Here, we experimentally demonstrate a technique for the direct measurement of the frequency chirp of extreme-ultraviolet free-electron laser pulses based on fundamental nonlinear optics. It is implemented in XUV-only pump-probe transient-absorption geometry and provides in-situ information on the time-energy structure of FEL pulses. Using a rate-equation model for the time-dependent absorbance changes of an ionized neon target, we show how the frequency chirp can be directly extracted and quantified from measured data. Since the method does not rely on an additional external field, we expect a widespread implementation at FELs benefiting multiple science fields by in-situ on-target measurement and optimization of FEL-pulse properties. Free-electron laser pulses generated from self-amplification of spontaneous emission scheme vary from one another in their characteristics. Here the authors demonstrate a transient absorption spectroscopy method to characterize the frequency chirp of the FEL pulses.

Automated summary

High-intensity ultrashort pulses at extreme ultraviolet (XUV) and x-ray photon energies delivered by state-of-the-art free-electron lasers (FELs) are transforming the field of ultrafast spectroscopy. A technique based on fundamental nonlinear optics has been experimentally demonstrated for the direct measurement of the frequency chirp of extreme-ultraviolet free-electron laser pulses, providing in-situ information on the time-energy structure of the pulses. By utilizing a rate-equation model, the frequency chirp can be directly extracted and quantified from measured data, without relying on an additional external field.