Open Quantum Systems: Liouville-space field theory

 

Lecture details

The lecture will be given by Professor Wegewijs.

Prerequisites:

quantum mechanics and statistical mechanics
second quantization + Wick theorem
suitable for students in the first Master semester

Topics:

The course develops quantum-field theoretical techniques for addressing open quantum systems out of equilibrium within a density-operator approach. Examples of such systems range from quantum dots realized in nanoscale devices (atoms, molecules, heterostructures) to quantum-information processing setups (e.g., readout-devices). Such open quantum systems can be strongly coupled to their environments and can be subject to external time-dependent driving, resulting, e.g., in pumping phenomena. This requires a systematic account of higher-order coupling effects and memory effects beyond the standard Born-Markov approximation. A general framework for performing such calculations is set up and is illustrated, focusing on transport problems involving quantum dots coupled to normal metal electrodes or ferromagnets.

The density operator approach has wide applicability and is used in particular by researchers working on quantum transport through strongly interacting systems as well as quantum information. A central notion is that of Liouville space, the space of physical mixed states of a quantum system coupled to (possibly competing) environments. The Liouville-space formalism that is presented provides a physically elegant and a technically efficient way of "importing" the usual techniques of quantum mechanics and field theory (which apply only to wave vectors) such that they also apply to density operators.

Basic topics:
- Liouville space formalism: physical density operators, superoperators, bra-ket formalism in Liouville space
- Quantum field operators for mixed states: second quantization and Wick-theorem in Liouville space
- Generalized quantum master equations for the density operator
- Symmetries for open quantum systems and superselection rules
- Diagrammatic perturbation theory time-evolution kernels: real-time and frequency space formulations, "Born-Markov" expansion, adiabatic expansion for time-dependently driven systems
- Transport of charge, spin and energy through quantum dots

Advanced topics introduced:
- Counting-statistics: calculation of distribution of 2-point measurement outcomes from a "counting-field" density operator, time-reversal and nonequilibrium fluctuation relations that quantify violation of thermodynamical laws
- Transient time-dependent decay after a parameter "quench"
- Adiabatic pumping of charge, spin and energy
- Renormalization of perturbation theory: exact resummation of "infinite-temperature" contributions leads to huge simplifications
- Renormalization group flow: real-time RG for nonequilibrium to access low-temperature and strong coupling to reservoirs

First lecture: Wednesday, April 13th: 2.15pm – 3.45pm Modulbau 2, Room MB2 102 (this is an office!).
Campus place + time are PLACEHOLDERS !


Note: The regular lecture and exercise class time and place will be optimally rescheduled based on the participants preferences.
Please contact Maarten Wegewijs if you cannot make it to the first lecture.

For the time schedule, you can also refer to the university calendar:

Time Schedule:

Time Room Start

Wed. 2.15pm - 3.45pm

4273 (MBP2 116)

13.04.2016 (14 dates)

Fri. 8.45am - 9.30am

4273 (MBP2 117)

15.04.2016 (14 dates)