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Complex shapes of photons to boost future quantum technologies

Published on 30.4.2021
Tampere University
Conceptual image of complex shapes of photons
Conceptual image of the used method for manipulating the spatial structures of photons using multiple consecutive lossless modulations. Image: Markus Hiekkamäki / Tampere University
Researchers at Tampere University Photonics Laboratory have demonstrated how two interfering photons can bunch into various shapes. These complex shapes are beneficial for quantum technologies, such as performing fast photonic quantum computations and safe data transfer. The method opens new possibilities also for creating enhanced measurement and sensing techniques.

As the digital revolution has now become mainstream, quantum computing and quantum communication are rising in the consciousness of the field. The enhanced measurement technologies enabled by quantum phenomena, and the possibility of scientific progress using new methods, are of particular interest to researchers around the world.

Recently two researchers at Tampere University, Assistant Professor Robert Fickler and Doctoral Researcher Markus Hiekkamäki, demonstrated that two-photon interference can be controlled in a near-perfect way using the spatial shape of the photon. Their findings were recently published in the prestigious journal Physical Review Letters.

Our report shows how a complex light-shaping method can be used to make two quanta of light interfere with each other in a novel and easily tuneable way”, explains Markus Hiekkamäki.

Single photons (units of light) can have highly complex shapes that are known to be beneficial for quantum technologies such as quantum cryptography, super-sensitive measurements, or quantum-enhanced computational tasks. To make use of these so-called structured photons, it is crucial to make them interfere with other photons.

“One crucial task in essentially all quantum technological applications is improving the ability to manipulate quantum states in a more complex and reliable way.  In photonic quantum technologies, this task involves changing the properties of a single photon as well as interfering multiple photons with each other;” says Robert Fickler, who leads the Experimental Quantum Optics group at the university.

Linear optics bring promising solutions to quantum communications

The demonstrated development is especially interesting from the point of view of high-dimensional quantum information science, where more than a single bit of quantum information is used per carrier. These more complex quantum states not only allow the encoding of more information onto a single photon but are also known to be more noise-resistant in various settings.

The method presented by the research duo holds promise for building new types of linear optical networks. This paves the way for novel schemes of photonic quantum-enhanced computing.

“Our experimental demonstration of bunching two photons into multiple complex spatial shapes is a crucial next step for applying structured photons to various quantum metrological and informational tasks”, continues Markus Hiekkamäki.

The researchers now aim at utilizing the method for developing new quantum-enhanced sensing techniques, while exploring more complex spatial structures of photons and developing new approaches for computational systems using quantum states.

“We hope that these results inspire more research into the fundamental limits of photon shaping. Our findings might also trigger the development of new quantum technologies, e.g. improved noise-tolerant quantum communication or innovative quantum computation schemes, that benefit from such high-dimensional photonic quantum states”, adds Robert Fickler.

Read more about research High-Dimensional Two-Photon Interference Effects in Spatial Modes.

Inquiries

Robert Fickler
tel.
+358 50 447 8492
robert.fickler [at] tuni.fi

What does the group research?

The Experimental Quantum Optics (EQO) group investigates light and its interaction with matter on the single quantum level. They are interested in answering fundamental questions of quantum physics, developing novel tools for quantum technologies, and studying light-matter interactions that are yet unexplored. Their research focuses on structuring single photons to realize high-dimensional quantum states and on investigating peculiar features such as quantum interference and entanglement. Read more on Experimental Quantum Optics group