2253 Homer A. Neal Lab
phone: 734.615.0726
About
Professor Gull works in the general area of computational condensed matter physics with a focus on the study of correlated electronic systems in and out of equilibrium. He is an expert on Monte Carlo methods for quantum systems and one of the developers of the diagrammatic ‘continuous-time’ quantum Monte Carlo methods. His recent work includes the study of the Hubbard model using large cluster dynamical mean field methods, the development of vertex function methods for optical (Raman and optical conductivity) probes, and the development of bold line diagrammatic algorithms for quantum impurities out of equilibrium. Professor Gull is involved in the development of open source computer programs for strongly correlated systems.
Selected Publications
Dynamics of Kondo Voltage Splitting After a Quantum Quench, I Krivenko, J Kleinhenz, G Cohen, E Gull, Physical Review B 100 (20), 201104 (2019).
Finite Temperature Quantum Embedding Theories for Correlated Systems, D Zgid, E Gull, New Journal of Physics 19 (2), 023047 (2017).
Solutions of the Two-Dimensional Hubbard Model: Benchmarks and Results from a Wide Range of Numerical Algorithms, (J. P. F. LeBlanc et al.), Phys. Rev. X 5, 041041 (2015).
Superconductivity and the Pseudogap in the Two-Dimensional Hubbard Model, (Emanuel Gull, Olivier Parcollet, and Andrew J. Millis), Phys. Rev. Lett. 110, 216405 (2013).
Continuous-time Monte Carlo Methods for Quantum Impurity Models, (Emanuel Gull, Andrew J Millis, Alexander I Lichtenstein, Alexey N Rubtsov, Matthias Troyer, Philipp Werner), Rev. Mod. Phys. 83, 349 (2011).
Field(s) of Study
- Condensed Matter Theory, Quantum Many-body Theory, Computational Condensed Matter Physics