The U.S. Department of Energy has granted approval for SLAC National Accelerator Laboratory—home of the Linac Coherent Light Source (LCLS), the world's first hard X-ray laser—to begin planning a 

SLAC's LCLS-II will occupy the second (left) half of the subterranean Undulator Hall, which was designed to accommodate a pair undulator arrays operating in tandem. The undulator array for LCLS-I, seen here, began generating pulses of X-ray laser light in April 2009. (Photo courtesy Brad Plummer/SLAC; click on image for larger version.)

second X-ray laser at the laboratory. The LCLS, which began operation in April 2009, generates ultra-fast, ultra-bright pulses of X-ray laser light which are already providing new insights into the atomic world. LCLS-II would give investigators access to new regions of the X-ray spectrum and improved control over the X-ray beam. It will also accommodate a larger number of research scientists working simultaneously.

The LCLS stands to revolutionize a variety of fields, including chemistry, biology and energy sciences. The LCLS is the world's first laser to create light in the form of hard X-rays, generated using SLAC's existing two-mile-long linear accelerator. The laser's ultra-fast, ultra-bright X-rays give scientists the ability to visualize matter on the atomic scale, where the action is measured in quadrillionths of a second. Scientists are now using LCLS beams to study how individual atoms and molecules move and behave, with an eye toward creating the world's first "molecular movies," revealing the mechanics of chemistry as it happens.

Although a number of hurdles remain before construction could begin, the current milestone, or "Critical Decision 0," granted by the DOE clears the way for scientific and technical teams to officially begin work on conceptual designs for LCLS-II.

The LCLS-II project will center on two new undulator arrays—the long series of magnets used to generate X-ray light from an electron beam—as well as an upgrade of the existing LCLS undulator. When complete, the facility will produce multiple X-ray beams that could operate either together or separately, with unprecedented flexibility and control over a much-extended range of X-ray energies—key to exploring precise regions of the atomic realm.

LCLS-II will provide the added capability of tailoring how the X-ray beam is polarized—essential, for example, for detailed studies of magnetism, which could lead to better information storage, and of exotic materials such as superconductors. The new capabilities will give researchers improved insights into processes like photosynthesis with the hope of creating more efficient methods for harvesting solar energy.

Importantly, the LCLS-II will address the surging demand for access within the scientific user community, by supplying multiple research groups with X-rays simultaneously, instead of serving a single user group at a time.

Source: SLAC Website