Researchers at the Max Planck Institute for the Science of Light in Erlangen are now able to use a laser to cause tiny particles to rotate around an axis perpendicular to the light beam—a particle thus rotates like the wheel of a bicycle in its direction of motion. The researchers achieved this by creating a photonic wheel: light with purely transverse angular momentum. This state of light was previously unknown. Physicists assumed that all light had propeller-shaped, longitudinal angular momentum. The new way of controlling light waves makes optical tweezers, which can be used to grip and manoeuvre cells and other micro-objects and nano-objects, more versatile.
Light can exert incredible forces. According to the rules of quantum mechanics, light is an electromagnetic wave, as well as a stream of photons. Since it has momentum, a transparent particle through which a light beam falls experiences a recoil when the photons leave it. Although the force which a photon exerts in this process is almost infinitesimal, the effect of innumerable light particles in intense and tightly focused laser beams adds up in such a way that objects up to a few micrometres can be held in an optical trap or moved in a specific way. Biologists, for example, use this effect in optical tweezers to fix cells and rotate them at the focus of a microscope. To this effect, scientists working with Gerd Leuchs, Director at the Max Planck Institute for the Science of Light, are now creating new possibilities for them.
The team has created a photonic wheel, i.e. light with purely transverse angular momentum: the electric field of the electromagnetic wave rotates about an axis whose orientation is perpendicular to the direction of motion, just like the axis of a wheel. Until now, physicists have mainly been familiar with light with longitudinal angular momentum where the electric field rotates like a propeller around an axis aligned along the direction of motion. “The possibility that light can have purely transverse angular momentum when averaged over the complete cross-section of the beam had not been realised before,” says Peter Banzer, who made a significant contribution to the discovery.
The light wheel is created in the focal plane of two circularly polarized beams
This is because, as the Erlangen-based physicists have now shown both theoretically and practically, it is indeed possible to generate light with purely transverse angular momentum—and what’s more it is surprisingly easy to do so. “Once it’s down on paper, it looks easy,” says Gerd Leuchs. But somebody has to come up with the idea in the first place. The researchers are now developing this idea using circularly polarized light. A wave of circularly polarized light turns like a screw around the direction of beam propagation and has propeller-like longitudinal angular momentum. Light with circular polarisation can be generated with the aid of a birefringent crystal, for example.
Whether the light wave turns clockwise or anticlockwise depends on the orientation of the crystal. The physicists in Erlangen combined two disks of this material such that one part of the laser beam rotates clockwise and the other part anticlockwise. They then used a lens to focus the two partial beams rotating in opposite directions onto a focal point of the size of the light’s wavelength. “Our theoretical considerations showed that we obtain light with purely transverse angular momentum in the focus—the photonic wheel,” says Peter Banzer. This special property is also evident in the experiment. They have already used a gold nanoparticle to measure the characteristic shape of the focal spot, which is closely related to the purely transverse angular momentum of the focused beam. As yet, there is still only indirect proof that the light field rotates about a transverse axis. However, the Erlangen-based physicists want to soon use the rotating light field to cause a nanoparticle to rotate about itself.
The light wheel will provide not only biologists with new experimental possibilities for rotating cells under the microscope in three spatial directions in the future. The new way of forming light waves extends the experimental scope in quantum optics and nano-optics as well. Moreover, it should prove useful in nanotechnology, to build nanomixers or other nanomachines, for example. “If we first accelerate particles in an optical trap in a circle and then open the trap, they should hurtle away as they spin, and we could organise a kind of dragster race with nanoparticles,” explains Gerd Leuchs. “In further experiments, we now want to explore the possibilities which the photonic wheel affords us.”
Source: Max Planck Institute