Matrix Product State applications for the ALPS project
- Michele Dolfi ,
- Bela Bauer ,
- Sebastian Keller ,
- Alexandr Kosenkov ,
- Timothée Ewart ,
- Adrian Kantian ,
- Thierry Giamarchi ,
- Matthias Troyer
Computer Physics Communications | , Vol 185: pp. 3430-3440
The density-matrix renormalization group method has become a standard computational approach to the low-energy physics as well as dynamics of low-dimensional quantum systems. In this paper, we present a new set of applications, available as part of the ALPS package, that provide an efficient and flexible implementation of these methods based on a matrix-product state (MPS) representation. Our applications implement, within the same framework, algorithms to variationally find the ground state and low-lying excited states as well as simulate the time evolution of arbitrary one-dimensional and two-dimensional models. Implementing the conservation of quantum numbers for generic Abelian symmetries, we achieve performance competitive with the best codes in the community. Example results are provided for (i) a model of itinerant fermions in one dimension and (ii) a model of quantum magnetism.