By using a beam of electrons, a team of accelerator physicists has found a new method to create coherent beams of twisted light.
Scientists at SLAC have found a new method to create coherent beams of twisted light – light that spirals around a central axis as it travels. It has the potential to generate twisted light in shorter pulses, higher intensities, and a much wider range of wavelengths, including X-rays, than is currently possible.
First described two decades ago, twisted light is attracting attention from researchers in fields as diverse as telecommunications, quantum computing, condensed matter research, and astronomy because of one unique property: It possesses orbital angular momentum (OAM). Twisted light has already been used by astronomers to find exoplanets, and researchers have demonstrated that it can transmit more information through fiber optic cables than the current industry standard.
Until now, researchers created twisted light by shooting laser beams through masks or holographic gratings. But a team of accelerator physicists from SLAC and UCLA has shown they can create it with a beam of electrons, in much the same way SLAC’s Linac Coherent Light Source (LCLS) X-ray laser uses electrons to generate pulses of X-ray laser light.
Creating twisted light at the NLCTA, SLAC’s test accelerator. (Greg Stewart/SLAC)
There are several advantages to generating corkscrew light beams this way, said SLAC postdoctoral researcher Erik Hemsing, who is lead author of a paper in the September issue of Nature Physics. Free-electron lasers can generate light in a vast range of wavelengths and in extremely short, bright pulses, opening up the possibility of generating OAM light at the X-ray wavelengths of, for example, LCLS.
“There are lots of other ways to make OAM light,” said Hemsing, “but most don’t translate to X-rays.”
The experiments were carried out at the Next Linear Collider Test Accelerator (NLCTA), SLAC’s small test accelerator. Although the OAM light the team coaxed out of their experimental setup was in the visible range, Hemsing said there’s no reason the same technique can’t be used to create OAM light of much shorter wavelengths, and thus much higher energies – X-ray energies.
The experiment is only one of several being conducted at NLCTA to create “beams by design,” or light with specific properties, by controlling the electrons that generate it, said Tor Raubenheimer, a professor of particle physics and astrophysics at SLAC and Stanford, who works closely with the NLCTA researchers.
“Erik is one of the young star physicists down at the NLCTA,” he said, “and has been part of a very productive physics program that is supported by both the Department of Energy Offices of Basic Energy Science and High Energy Physics.”
The research is a continuation of work done in photon science facilities, from synchrotron light sources like SLAC’s Stanford Synchrotron Radiation Lightsource to free-electron lasers like the LCLS, where scientists have learned how to control and shape the electron bunches used to generate light. At the most advanced facilities, such as the LCLS, bunches of accelerated electrons are sent through undulators – exquisitely tuned series of magnets that force the electrons to wiggle back and forth in such a way they generate laser light.
In the case of corkscrewing light, researchers send two pulses – one containing electrons, the other laser light – through an undulator simultaneously.
The combination of laser pulse and undulator imprints an energy pattern on the electrons. As they pass through another grouping of magnets called a chicane, the electrons reposition themselves like race cars on a curve, and hit the next straightaway arranged in the shape of a corkscrew. This “helically microbunched” arrangement of electrons then enters a second undulator that causes them to wiggle and emit spiraling light.
Intense beams of spiraling X-ray light could open the door to new condensed matter research, said Hemsing. But there is one challenge to overcome: As with the development of the first X-ray lasers, technology is ahead of demand. Researchers who could take advantage of the special properties of OAM light don’t necessarily know it’s available or what it could do for them.
But the success of LCLS should make things easier, showing the potential for working with new forms of light. “People can see how well the LCLS works,” said Hemsing. “Now they’re interested in what other kinds of light we can make.”
Reference: “Coherent optical vortices from relativistic electron beams” by Erik Hemsing, Andrey Knyazik, Michael Dunning, Dao Xiang, Agostino Marinelli, Carsten Hast and James B. Rosenzweig, 18 August 2013, Nature Physics.