Abstract
A broadband energy-chirped hard X-ray pulse has been demonstrated at the SwissFEL (free electron laser) with up to 4% bandwidth. We consider the characteristic parameters for analyzing the time dependence of stationary protein diffraction with energy-chirped pulses. Depending on crystal mosaic spread, convergence, and recordable resolution, individual reflections are expected to spend at least ≈ 50 attoseconds and up to ≈ 8 femtoseconds in reflecting condition. Using parameters for a chirped XFEL pulse obtained from simulations of 4% bandwidth conditions, ray-tracing simulations have been carried out to demonstrate the temporal streaking across individual reflections and resolution ranges for protein crystal diffraction. Simulations performed at a higher chirp (10%) emphasize the importance of chirp magnitude that would allow increased observation statistics for the temporal separation of individual reflections for merging and structure determination. Finally, we consider the fundamental limitation for obtaining time-dependent observations using chirped pulse diffraction. We consider the maximum theoretical time resolution achievable to be on the order of 50–200 as from the instantaneous bandwidth of the chirped SASE pulse. We then assess the ability to propagate ultrafast optical pulses for pump-probe cross-correlation under characteristic conditions of material dispersion; in this regard, the limiting factors for time resolution scale with crystal thickness. Crystals that are below a few microns in size will be necessary for subfemtosecond time resolution.
Highlights
With serial femtosecond crystallography (SFX) at X-ray Free Electron Lasers (XFELs), pump-probe data of protein structural dynamics with femtosecond time resolution can be obtained
The aim of this work is to evaluate the time resolution, ∆tres, that would theoretically be achievable in a polychromatic XFEL experiment from considerations of physical parameters for protein crystallography
The analysis presented here concludes that, given the polychromatic chirped XFEL pulse currently available at SwissFEL, the instantaneous bandwidths throughout the pulse correspond to time intervals between ≈ 50–150 as
Summary
With serial femtosecond crystallography (SFX) at X-ray Free Electron Lasers (XFELs), pump-probe data of protein structural dynamics with femtosecond time resolution can be obtained. In an SFX experiment, protein structures are determined by merging thousands of stationary diffraction patterns from single femtosecond XFEL pulse exposures. The bandwidth for an XFEL pulse, when operated in self-amplified spontaneous emission (SASE) mode, is on the order of ∆E/E ≈ 0.2% [8,9,10]. The SASE process relies on the emission of spontaneous radiation by electrons in the first section of an undulator that is itself the X-ray seed for the FEL [11,12,13,14]. As spontaneous radiation emission from the electrons is stochastic, the SASE.
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