Physicists have just done something they thought impossible
Scientists have created a hologram of a solitary particle of light. Image: REUTERS/Edgar Su
Until recently, scientists didn't think it could be done. They thought the fundamental laws of physics would forbid it. But a persistent group of scientists at the University of Warsaw have now accomplished the impossible: They created a hologram of a solitary particle of light.
This accomplishment is ushering in a new era of quantum holography, which will give scientists a new way of looking at quantum phenomena.
Quantum holograms
Unlike photography, holography recreates the spatial structure of objects, giving us their 3-D shapes. The technique takes advantage of something called classical interference, which is when two waves meet and form a new wave.
But classical interference is impossible with photons, since their phases (a property of waves) are constantly fluctuating. So the Warsaw physicists tried to give quantum holograms a taste of their own medicine by using quantum interference, in which photons' wave functions (which have to do with the probability of the particle being in a particular state) interact.
"Wave function is a fundamental concept in quantum mechanics and the core of its most important principles, the Schrödinger equation," according to Phys.org. "In the hands of a skilled physicist, the function could be compared to putty in the hands of a sculptor. When expertly shaped, it can be used to 'mould' a model of a quantum particle system."
So why photons?
While filming the behavior pairs of photons, Radoslaw Chrapkiewicz and Michal Jachura, two of the researchers, noticed something called two-photon interference.
In two-photon interference, pairs of distinguishable photons act randomly when entering a beam splitter (which divides a ray of light). But nondistinguishable photons exhibit quantum interference, which affects their behavior. The pairs are always either transmitted or reflected together.
"Following this experiment, we were inspired to ask whether two-photon quantum interference could be used similarly to classical interference in holography in order to use known-state photons to gain further information about unknown-state photons. Our analysis led us to a surprising conclusion: It turned out that when two photons exhibit quantum interference, the course of this interference depends on the shape of their wavefronts [an imaginary surface joining all adjacent points with the same phase]," Chrapkiewicz told Phys.org.
Understanding quantum mechanics
This experiment has huge implications for our understanding of the fundamental laws of quantum mechanics, a field of physics that has been perplexing scientists for more than a century. It allows scientists to gain valuable information about the phase of a photon's wave function.
"Our experiment is one of the first allowing us to directly observe one of the fundamental parameters of photon's wave function — its phase — bringing us a step closer to understanding what the wave function really is," Jachura said.
The researchers hope to apply this method to create holograms of more complex quantum objects, which might have implications that stretch beyond fundamental science into real world applications.
"All of us — I mean physicists — must first get our heads around this new tool," said Konrad Banaszek, a researcher in the experiment. "It's likely that real applications of quantum holography won't appear for a few decades yet, but if there's one thing we can be sure of, it's that they will be surprising."
Read more:
Don't miss any update on this topic
Create a free account and access your personalized content collection with our latest publications and analyses.
License and Republishing
World Economic Forum articles may be republished in accordance with the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International Public License, and in accordance with our Terms of Use.
The views expressed in this article are those of the author alone and not the World Economic Forum.
Stay up to date:
Emerging Technologies
Forum Stories newsletter
Bringing you weekly curated insights and analysis on the global issues that matter.
More on Emerging TechnologiesSee all
Michele Mosca and Donna Dodson
December 20, 2024