Submitted via IRC for Bytram
Video of a phenomenon: Standing waves that won't stand still
And yet they move: An international team of scientists involving physicists from the Center for Nanointegration (CENIDE) at the University of Duisburg-Essen (UDE) has observed a new phenomenon: They have generated standing waves – which travel. The results of their research have been published in the scientific journal "Physical Review B", including videos.
A wave consists of antinodes and nodes. If you imagine this on a rope, the antinodes are the areas which swing up and down, whereas nodes are the points in between. With a standing wave, nodes and antinodes always remain at the same position and do not move along the rope.
In travelling waves on the other hand, nodes and antinodes do not remain in place: If you start shaking a rope from one end, you will excite a wave that travels down the rope until it reaches the other end.
Benjamin Zingsem from the research group of UDE's Professor Michael Farle has now observed the apparent paradox for the first time: For this purpose, he worked with, what physicists call a chiral magnet:
A magnetic material in which the so called Dzyaloshinskii-Moriya interaction occurs. In such magnets, all dipoles – the tiny magnets that make up the solid – are slightly tilted towards each other with a certain direction, like screw windings.
If the system is resonantly excited, a standing wave with travelling properties is formed. This wave has stationary nodes and antinodes, but at the same time a continuous phase shift creates the impression of a travelling wave. "I had to look at it for a long time before I could put it into words. I only really understood it by watching a video of the phenomenon," says Zingsem.
The effect reveals previously unknown transport properties in such systems. Which may, for example, be harnessed in future technology, as, information can be stored, transmitted and processed via magnetic oscillations without generating heat, which is the main bottleneck in conventional electronics.
(Score: 2) by AthanasiusKircher on Wednesday August 14 2019, @10:48AM
Yep. And I'd say that's a somewhat rare property of a waveform. Not unique, and perhaps not mathematically groundbreaking, but an unusual property.
I have no idea whether that means those kinds of characteristics mean these waves can do the stuff TFA claims (as I can't read the original study), but the vast majority of waves don't have the characteristics you described, which was my point.