New (10/2012): Currently, I can accept doctoral students only if they qualify for the Graduate School of Excellence "MAterials science IN mainZ" (MAINZ). Highly qualified postdocs with experience in strongly correlated electron systems, ultracold atoms on optical lattices, and/or state-of-the-art numerical techniques (quantum Monte Carlo, density-matrix renormalization group, ...) are also welcome to apply.

Please make your application (to Nils.Bluemer@uni-mainz.de) as specific as possible: refer to this page, to a specific project, mention relevant papers, etc. Demonstrate explicitly why you are a good candidate for the particular project that you are applying for. In the case of a serious and substantial application, feel free to follow up within about 14 days or give me a call if I haven't replied yet. If we have already met of if you have a prominent relevant publication: call right away.

Doktorarbeiten

Nur für Kandidaten mit guten Englischkenntnissen:

PhD theses

Doctoral students are currently sought for one DFG funded project.

Multi-flavour Mott transitions and magnetism of ultracold quantum gases on optical lattices

This project is part (within subject area A Model-based Systems) of the transregional research initiative SFB-TR49 Condensed Matter Systems with Variable Many-Body Interactions (Frankfurt, Mainz, Kaiserslautern) which was founded in 2007; the current extension proposal (until 2015) will be reviewed in April 2011.

Multiflavour mixtures of ultracold fermionic atoms on optical lattices provide unique opportunities for studying a wide range of correlation effects with direct access to the relevant control parameters. This has already been demonstrated for the paramagnetic Mott metal-insulator transition; it is expected that also the generic low-temperature antiferromagnetism (or at least precursors thereof) will soon be seen in 2-flavour experiments, possibly using the detection scheme developed in this project [1]. Once this milestone is accomplished, cold-atom systems may serve as quantum simulators of strongly correlated materials and, thereby, help solve both fundamental and technically relevant open questions in this field. The central goal of this project is to develop appropriate theoretical tools for cold-atom specific aspects of correlation physics and to explore both the analogies and fundamental differences between correlated cold-atom systems and materials, with a specific focus on genuine multi-flavor effects.

Due to their tunability, cold-atom systems also appear as natural systems for controlled studies of flavor inequivalence, frustration, and of local inhomogeneities. We are going to address fundamental questions such as the relation between lattice types, the number of flavors and the resulting frustration effects (e.g. a triangular lattice is frustrated for 2-flavor mixtures, but not for balanced 3-flavor mixtures). Moreover, we will predict how a single impurity or few impurities alter the correlation physics in inhomogeneous systems. Selected issues will be studied in a direct material context, in close collaboration with TR49 projects belonging to subject area B Solid State Real Materials.

[1] E. V. Gorelik, I. Titvinidze, W. Hofstetter, M. Snoek, and N. Blümer, Néel transition of lattice fermions in a harmonic trap: a real-space dynamical mean-field study, Phys. Rev. Lett. 105, 065301 (2010) [arXiv:1004.4857].

Prerequisites: Solid background in condensed matter theory, experience with quantum many-body problems (ideally including Hubbard type models), programming skills.

Completed PhD theses

2002 - 2006  Carsten Knecht: Numerical and analytical approaches to strongly correlated electron systems (co-supervised, main supervisor: Prof. van Dongen).
2006 - 2010  Eberhard Jakobi: Numerische und analytische Untersuchungen stark korrelierter fermionischer Mehrbandsysteme.

Diplomarbeiten

Ich vergebe jederzeit Diplomarbeiten auf meinem Forschungsgebiet (Theorie stark korrelierter Elektronensysteme), insbesondere zur numerischen Auswertung der Dynamischen Molekularfeldtheorie (DMFT) mit Hilfe von Quanten-Monte-Carlo (QMC)-Simulationen.

Voraussetzungen:

Diploma theses

Diploma theses are assigned within my research area (theory of strongly correlated electron systems), in particular on the numerical evaluation of the dynamical mean-field theory (DMFT) using quantum Monte Carlo (QMC) simulations.

Prerequisites: