IDW published a news piece on QUDICE -Press release disseminated by the Fraunhofer Institute for Applied Optics and Precision Engineering IOF

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Research projects, Quantum communication satellite

An international team of EU researchers is working towards the goal of using entangled light particles for practically tap-proof communication in Europe. Within the new QUDICE project, they will collaboratively develop components and systems for space-based quantum key distribution. QUDICE aims to make a significant contribution to the future realization of a European network of satellites for quantum-based communication. Such a network will specifically protect the privacy of European institutions, companies, and citizens, while bolstering Europe’s independence from critical (quantum) technologies originating from abroad.

Compact and highly efficient photon pair source for use in space

Within the framework of QUDICE, a miniaturized, space-qualified polarization-entangled photon pair source (EPS) in the telecommunications wavelength range will be built at the Fraunhofer IOF in Jena. This source will later be integrated into a satellite. The photon pair source must therefore meet special requirements for use in space: For example, it must be particularly small and compact. The aim is to achieve a size similar to that of a one liter milk carton.

Fraunhofer and ICFO Partner on Quantum Tech for Space

The researchers at Fraunhofer IOF must therefore miniaturize all the individual components of the source and integrate them on several chips. Furthermore, the source must be able to withstand strong vibrations as well as large temperature fluctuations, which occur during the launch of the satellite on its way into space. The photon pair source will therefore be based on recent advances in nonlinear optics and engineering. The goal for the new source is to achieve 10^9 pairs of entangled light particles per second and a bit rate that exceeds the current state of the art by several orders of magnitude.

Fraunhofer IOF will work closely with the Institute of Photonic Sciences (ICFO) from Spain – one of twelve partners in the QUDICE project – to construct the photon pair source in space-qualified quality. Together, the institutes will develop a novel design for the entangled photon source, which will allow the integration of the components and thus a particularly compact setup. To this end, ICFO will design specific subsystems for each chosen QKD implementation, while Fraunhofer IOF will implement them. Subsequently, the Fraunhofer Institute in Jena will characterize all opto-electronic components, while ICFO will perform the QKD implementations.

Strengthening Europe’s technological sovereignty in quantum technologies

Already in 2019, an agreement between the EU Commission and the European Space Agency (ESA) took the first step towards the development of a highly secure pan-European infrastructure for increased data security. Quantum key distribution represents a crucial enabling technology in this regard. QUDICE is intended to drive forward the corresponding research and development work. The project is therefore being funded by the European Union within the framework of the “Horizon Europe” program with 4.3 million euros. 450,000 euros of this will flow into the work at Fraunhofer IOF in Jena.

A Global Consortium Advancing Quantum Key Exchange via Satellite

The realization of the project goal requires expertise from a wide range of fields – from quantum physics, mechanical engineering, and optical engineering to radio communications, satellite technology, and space technology. Through the collaboration of world-leading research institutions as well as technology developers and manufacturers, but also system integrators, an interdisciplinary consortium is formed in which leading experts from their respective fields are gathered.

In addition to the Fraunhofer IOF, the partners of the QUDICE project are: University of Padova, ThinkQuantum SRL, Stellar Project SRL, Argotec, Thales Alenia Space (all Italy), The Institute of Photonic Sciences ICFO, Quside SL, Sateliot IOT Services SL (all Spain), Centre National de la Recherche Scientifique, Sorbonne Université (all France), L Università ta’ Malta (Malta).

Researchers at Fraunhofer IOF have repeatedly demonstrated the exchange of quantum keys over various paths and distances. They have achieved this using free beams within a city and via optical fibers laid between different metropolitan regions. However, quantum key exchange via satellite also allows connectivity in areas where fiber connectivity is impossible or limited, such as offshore locations. Additionally, space-based quantum key exchange offers a reliable backup in the event of a natural disaster destroying fiber-based infrastructures or a widespread network outage.

FAQ: Questions and answers around quantum (communication)

What are quanta anyway?

The world is a quantum world. That means: Everything consists of quanta, as long as we look at sufficiently small systems. Because quanta are the smallest and indivisible units that cause physical interactions. Photons, i.e., particles of light, are therefore also tiny quantum objects.

These quantum objects have fascinating properties that researchers are exploiting in the development of cutting-edge quantum technologies. One special property is the entanglement of quantum objects. Entanglement here means that pairs of entangled particles (e.g., photons) are created. Each particle always knows the exact state of its “twin” – even if the twin is far away.

How can we protect our data and communication with the help of quanta? And what are quantum keys or QKD in this context?

Our highly networked modern world faces particular vulnerability to cyberattacks. Attacks on critical infrastructure, such as nuclear power plants, can endanger not only sensitive data but potentially lives. Currently, cryptographic algorithms based on solving complex numerical problems encrypt our communication systems. However, the anticipated emergence of quantum computing, next-generation high-performance computers capable of solving problems within seconds that would take conventional computers years, as well as potential breakthroughs in mathematics, pose a long-term threat to this method’s security.

Therefore, we need new approaches to ensure the long-term security of our data today. Communication utilizing quantum technology promises a completely new level of security. Unlike conventional cryptographic methods, quantum cryptography relies on physical principles. Quantum key distribution (QKD) forms the technological basis for this. QKD allows legitimate users to share random keys, guaranteeing special security based on the laws of quantum mechanics rather than an adversary’s computing power.

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