In the 1920s, Erwin Schrödinger wrote an equation that predicts how particles-turned-waves should behave. Now, researchers are perfectly recreating those predictions in the lab
Peter Schauss at the University of Virginia says the wave packet is such a well-understood component of quantum theory that the findings of the new experiment are not surprising – but they do show that the researchers had a high degree of control over the processes used to cool and then precisely image the atoms.
I'm not entirely sure what they mean by having images of their waviness, because that is not how it works. You can not measure a quantum wave, because it isn't a "particle" wave but a wave-like distribution of mutually exclusive measurement outcomes. Taking a picture is the same as entangling yourself, which embeds you in the quantum wave function such that it describes all possible combinations of you ending up with every possible outcome.
As I understand it, they are making measurements of an otherwise single isolated particle as it moves about in a controlled space, and the measurements confirm (yet again) that the measurement outcomes match the probabilities given by the Schrödinger equation, which means that it interferes with itself.
The language used may lead some to think that we now have images showing a wave-like particle, but again, that's not something that can ever happen. What we have are boring old images of a single classical-looking particle, but the patterns they display tells us that quantum mechanics is very much at play in between the takes.