Free-electron lasers and JSR
`X-ray Laser Advances' featured in the top ten for `Breakthrough of the Year 2012' (http://www.sciencemag.org/site/special/btoy2012/ ) chosen by the journal Science. The determination of new details in the crystal structure of the trypanosomal protein Cathepsin B was recognized by the award (Redecke et al., 2013). Diffraction data of tiny in vivo grown crystals were collected using intense femtosecond X-ray free-electron laser (FEL) flashes from the LINAC Coherent Light Source (LCLS), the first hard X-ray FEL (Emma et al., 2010).
The technical and scientific progress enabled by X-ray FELs is astounding. The changes are as dramatic as some 30 years ago when dedicated storage rings began to come into operation. The same sense of excitement prevails and similar pioneering spirits are shared by the community. The LCLS, the first hard X-ray laser to become operational, provides, for example, X-ray flashes with pulse durations as short as sub-ten femtoseconds, containing up to 1013 transversely coherent photons in a narrow spectral bandwidth, at X-ray energies ranging from 500 eV to 10 keV. Typical irradiances obtainable by focusing are in the 1018 to 1021 W cm−2 range.
Since the commissioning of the LCLS in 2009, both long-anticipated and unexpected results have been obtained. For example, the concept of diffraction before destruction, first proposed by Solem in 1986, has been demonstrated for viruses (Seibert et al., 2011), protein nanocrystals (Chapman et al., 2011) and airborne particulate matter (Loh et al., 2012), indicating that nuclear-motion-based damage effects can be outrun if sufficiently short intense X-ray pulses are used (Solem, 1986; Neutze et al., 2000). Nevertheless, electronic damage takes place and multiphoton absorption results in very rapid sequential photoejection of inner-shell electrons, producing `hollow' atoms and an intensity-induced X-ray transparency in light atoms (Young et al., 2010). Unexpectedly, in high-Z atoms, charge states have been observed that are higher than those achievable by the last ionic state that can be ionized with one photon. These high-charge states are created via excitation of transient resonances in highly charged ions (Rudek et al., 2012). This severe electronic damage may be exploited for high-intensity multiwavelength anomalous dispersion phasing approaches for crystal structure determination using FELs (Son et al., 2011).
Different machine concepts have been realised and are being developed further. First seeding approaches have been implemented to improve the quality and properties of the SASE beam (Shintake et al., 2008). Currently, the LCLS in Stanford, USA, and SACLA in Harima, Japan, are the only hard X-ray FELs. To increase the availability of this scarce resource, different concepts for multiplexing are currently being explored.
New FELs are being built such as the SwissFEL, the European XFEL, the Korean FEL and LCLS-II, an upgrade of the LCLS. Given the exciting developments with FELs, the Journal of Synchrotron Radiation's intensified coverage of free-electron lasers, which is now prominently reflected on the journal's cover, is very timely. The journal provides a home for rapid communications of scientific results obtained with these sources as well as of developments in instrumentation and methods. I was brought in as an Editor to serve as a point of contact for FEL-related topics and I am looking forward to serving the wider FEL community as well as the synchrotron radiation structural biology community. We plan to put together a special issue on Free-Electron Laser Science and Technology where we will be soliciting authors who have something `special' to communicate to the wider community of synchrotron radiation and FEL scientists, may they be chemists or biologists, condensed matter physicists or material scientists. We wish to make the Journal of Synchrotron Radiation the natural home for reporting the technical advances as well as the scientific breakthroughs in the field.
Chapman, H. N. et al. (2011). Nature (London), 470, 73–77. Web of Science CrossRef CAS PubMed
Emma, P. R. et al. (2010). Nat. Photon. 4, 641–647. Web of Science CrossRef CAS
Loh, N. D. et al. (2012). Nature (London), 486, 513–517. Web of Science CrossRef CAS PubMed
Neutze, R., Wouts, R., van der Spoel, D., Weckert, E. & Hajdu, J. (2000). Nature (London), 406, 752–757. Web of Science CrossRef PubMed CAS
Redecke, L. et al. (2013). Science, 339, 227–230. Web of Science CrossRef CAS PubMed
Rudek, B. et al. (2012). Nat. Photon. 6, 858–865. Web of Science CrossRef CAS
Seibert, M. M. et al. (2011). Nature (London), 470, 78–81. Web of Science CrossRef CAS PubMed
Shintake, T. et al. (2008). Nat. Photon. 2, 555–559. Web of Science CrossRef CAS
Solem, J. C. (1986). J. Opt. Soc. Am. B, 3, 1551–1565. CrossRef CAS
Son, S.-K., Chapman, H. N. & Santra, R. (2011). Phys. Rev. Lett. 107, 218102. Web of Science CrossRef PubMed
Young, L. et al. (2010). Nature (London), 466, 56–61. Web of Science CrossRef CAS PubMed
© International Union of Crystallography. Prior permission is not required to reproduce short quotations, tables and figures from this article, provided the original authors and source are cited. For more information, click here.