Quantum Simulation with Universal Nonlinear optics

Quantum information processing is a transformative technology that will address societal needs by obtaining unprecedented computational power with quantum computers and simulators, unconditionally secure quantum communications, and quantum-enhanced sensors.

Photons play a central role in the development of quantum technologies due to their unique capability to encode quantum information with low-noise, transmit it over long distances, and process it in scalable photonic circuits.

However, the lack of photon-photon nonlinearities poses a central challenge in the development of photonic quantum technologies. The aim of this proposal is to address this limitation for next-generation quantum photonic devices.

The enabling technology is the combination of two quantum photonic platforms: light-matter interactions with quantum dot emitters in integrated nanostructures, and programmable quantum photonic circuits performing universal transformation in the temporal degree of freedom.

Through the use of high-quality light-matter interfaces and efficient interconnection with photonic circuitry, this project will (1) develop devices able to perform high-quality programmable nonlinear circuits, and (2) demonstrate how such devices can be used to implement near-term applications, focusing on the quantum simulation of anharmonic molecular dynamics.

The developed platform solves a critical set of challenges that have limited the scaling of quantum photonic devices, enabling transformative quantum photonic technologies for quantum computing and networking.

The synergy between my strong experience in programmable quantum photonic devices and applications, the world-leading expertise of Prof.

Lodahls host group in integrated light-matter interactions, and the high interdisciplinarity of the Niels Bohr Institute and University of Copenhagen, makes us uniquely placed to execute this ambitious project.