Surfers spend much of their time watching long waves come onto the shoreline as they attempt to catch one right as it begins to curve and break.
In a similar vein, scientists are working to create twisting helical electromagnetic waves whose curvature allows more accurate imaging of the magnetic properties of different materials at the atomic level and could possibly lead to the development of future devices.
When scientists use electron beams to look at samples of materials, they have the ability to modify many different aspects of the electromagnetic waves that make up the beam. They can make the amplitude of the waves bigger or smaller, or make the waves faster or slower. However, until now there has been no easy way to transform a plane wave—like the long rolling waves out at sea—into a helical wave, like the ones that crash onshore.
In a new study from the U.S. Department of Energy's (DOE) Argonne National Laboratory, scientists have created small regions of magnetic defects made from nanoscale magnetic islands assembled into a grid. The plane waves interact with these defects, thereby generating helical waves.
"We're looking for waves with a kind of perfect curl, and in order to generate the curl we need to give them something to crash into, which in our case are magnetic monopoles," said Argonne materials scientist Charudatta (C.D.) Phatak.
The reason scientists are so interested in helical waves is that they have a property called orbital angular momentum. Knowing the orbital angular momentum of an electron beam allows scientists to investigate the magnetic behavior of materials at an atomic level by determining an atomic property called the magnetic moment.
"If we can see the magnetic moments of the material, we can build a description of the total magnetic properties of the material, and how the material will manifest its electronic and magnetic properties," Phatak said.
In this way, the refigured electron beam could be useful for studying materials in which spin and magnetization play a crucial role, potentially paving the way towards new forms of electronic devices.