The Quantum Machines Unit develops, both theoretically and experimentally, devices that bring disparate types of individual quantum sub-systems together to function collectively in performing useful tasks. Applications of quantum machines range from developing tomorrow’s quantum computer networks to creating ultraprecise magnetometers for biomedical imaging and inertial navigation.

What we do: Quantum science and technology seeks to develop new types of applications based on the properties and dynamics of the quantum world. We already know that using quantum science there is the potential to build enormously faster computers – quantum computers, but there are many other potential applications ranging from ultra-precise quantum assisted sensors through to new types of simulators of complex quantum phenomena. Our understanding of the quantum realm and engineering it to our design is just beginning. As our facility at controlling the quantum improves we will invariably seek to build QUANTUM MACHINES, machines made from disparate quantum sub-systems, all working together to achieve a designed goal which no individual sub-system can achieve. Almost all machines made by humans are made up from interconnected parts, each doing their sub-function to enable the complete machine to achieve fantastically new abilities, e.g. cars, planes, computers. This unit seeks to understand how one can interconnect individual, sometimes very different, quantum systems – in order to achieve a new functionality not possible within each individual sub-system.

Quantum Sensors and Networks: The potential range of quantum machines range from developing a quantum network – where flying quantum bits (photons), have to talk coherently with a static quantum sub-systems (trapped ions, superconductors, spins in solids), through to quantum sensors where various types of quantum systems enable the user to achieve unprecedented precision in performing e.g. inertial sensing, or magnetic field sensing.

Theory & Experiment: The Unit works on developing theoretical designs for integrated quantum machines and in addition on experimental prototypes for quantum machines using magnetically levitated quantum materials.