The aim of this lecture is to provide the tools to tackle advanced and "real-life" problems in quantum theory and quantum technologies and to set the basis for advanced lectures including quantum information theory, quantum optics, condensed matter theory, atomics and molecular physics, and quantum field theory.
In this seminar, we want to discuss recent advances in quantum technologies. Each presentation will focus on one recent scientific publication and provide the necessary background on the respective subfield.
This lecture introduces core physical and mathematical concepts in quantum computing and quantum information theory. This includes quantum algorithms and computational complexity theory, physical realizations of qubit systems, errors and error correction.
We offer two research-lab projects: "Simulating a quantum computer", supervised by Adrian Aasen. "Entanglement in quantum field theory" supervised by Mauro D'Achille.
In this seminar, we want to discuss recent advances in quantum technologies. Each presentation will focus on one recent scientific publication and provide the necessary background on the respective subfield.
The aim of this lecture is to provide the tools to tackle advanced and "real-life" problems in quantum theory and quantum technologies and to set the basis for advanced lectures including quantum information theory, quantum optics, condensed matter theory, atomics and molecular physics, and quantum field theory.
In this seminar, we want to discuss recent advances in quantum technologies. Each presentation will focus on one recent scientific publication and provide the necessary background on the respective subfield.
This lecture gives an introduction to quantum computing, sensing, and communication, with a focus on basic mathematical and physical concepts underpinning these emerging quantum technologies.