Here you will find information about the projects that are funded and started through the European Quantum Flagship initiative.
The Quantum Flagship’s new Coordination and Support Action ‘QUCATS’ will strengthen the Flagship’s foundations and steer it through the next phase, in which European quantum technologies mature and the ecosystem of initiatives expands.
2D-SIPC will search to bring solutions to quantum communications by providing on-chip quantum devices for quantum integrated photonic circuits to enable secure communication protocols, scaling of quantum computers, and development of novel quantum sensing applications.
This project focuses on the scalability, availability, and applicability aspects of trapped-ion quantum computers, tackling the transition from current laboratory-based experiments to industry-grade quantum computing technologies.
ASTERIQS will exploit quantum sensing based on nitrogen-vacancy-centers in ultrapure diamond to bring solutions to societal and economical needs for which no solution exists yet.
The vision of CIVIQ is to develop quantum-enhanced physical layer security services that can be combined with modern cryptographic techniques, to enable unparalleled applications and services.
Optical clocks are amazingly stable frequency standards, which would be off by only one second over the age of the universe. Bringing those clocks from the laboratory into a robust and compact form will have a large impact.
macQsimal is an EU-funded Horizon 2020 research project which will design, develop, miniaturize and integrate advanced quantum-enabled sensors with outstanding sensitivity, to measure physical observables in five key areas: magnetic fields, time, rotation, electromagnetic radiation, and gas concentration.
Cardiovascular diseases are one of the most common causes of death worldwide. Therefore, it is necessary to develop personalized medical solutions to improve the chances of curing patients. In order to do so, the metabolic process of heart tissue needs to be understood and observed on a molecular level.
The construction of a large-scale trapped-ion quantum information processor can be made decisively simpler by using the well-developed and compact microwave technology present already in today’s mobile phones and other devices.
