11 Oct 2022
Discovery by Tampere University Quantum Optics Group promises more sensitive distance measurements and more.
Researchers at Tampere University, Finland, have shown that quantum light with a well-defined photon number behaves differently to standard focused laser beams. They say this finding “both deepens understanding of the phenomena and enables super-sensitive distance measurements”.
Optics, the study of light, is one of the oldest fields in physics and has never ceased to surprise researchers. Although the classical description of light as a wave phenomenon is rarely questioned, the physical origins of some optical effects are. A team of researchers at Tampere University have brought the discussion on one fundamental wave effect, i.e., the debate around the anomalous behaviour of focused light waves, to the quantum domain.
They been able to show that quantum waves behave significantly differently from their classical counterparts and can be used to increase the precision of distance measurements. T findings also add to the discussion on physical origin of the anomalous focusing behaviour. The work is described in Nature Photonics.
“Interestingly, we started with an idea based on our earlier results and set out to structure quantum light for enhanced measurement precision. However, we then realised that the underlying physics of this application also contributes to the long debate about the origins of the Gouy phase anomaly of focused light fields,” said Robert Fickler, group leader of the Experimental Quantum Optics group at Tampere University.
Over recent decades, methods for structuring light fields down on the single photon level have vastly matured and led to a myriad of novel findings. In addition, a better of optics’ foundations has been achieved.
However, the physical origin of why light behaves in such an unexpected way when going through a focus, the so-called Gouy phase anomaly, is still often debated. This is despite its widespread use and importance in optical systems. The novelty of the current study is now to put the effect into the quantum domain.
“When developing the theory to describe our experimental results, we realised after a long debate that the Gouy phase for quantum light is not only different than the standard one, but its origin can be linked to another quantum effect. This is just like what was speculated in an earlier work,” adds Doctoral researcher Markus Hiekkamäki, leading author of the study.
In the quantum domain, the anomalous behaviour is sped up when compared to classical light. As the Gouy phase behaviour can be used to determine the distance a beam of light has propagated, the speed up of the quantum Gouy phase could allow for an improvement in the precision of measuring distances.
With this new understanding at hand, the researchers are planning to develop novel techniques to enhance their measurement abilities such that it will be possible to measure more complex beams of structured photons. The team expects that this will help them push forward the application of the observed effect, and potentially bring to light more differences between quantum and classical light fields.