Thermal coupled cluster theory for SU (2) systems
Physical Review B, 2022•APS
Coupled cluster (CC) has established itself as a powerful theory to study correlated quantum
many-body systems. Finite-temperature generalizations of CC theory have attracted
considerable interest and have been shown to work as nicely as the ground-state theory.
However, most of these recent developments address only fermionic or bosonic systems.
The distinct structure of the su (2) algebra requires the development of a similar thermal CC
theory for spin degrees of freedom. In this paper, we provide a formulation of our thermofield …
many-body systems. Finite-temperature generalizations of CC theory have attracted
considerable interest and have been shown to work as nicely as the ground-state theory.
However, most of these recent developments address only fermionic or bosonic systems.
The distinct structure of the su (2) algebra requires the development of a similar thermal CC
theory for spin degrees of freedom. In this paper, we provide a formulation of our thermofield …
Coupled cluster (CC) has established itself as a powerful theory to study correlated quantum many-body systems. Finite-temperature generalizations of CC theory have attracted considerable interest and have been shown to work as nicely as the ground-state theory. However, most of these recent developments address only fermionic or bosonic systems. The distinct structure of the algebra requires the development of a similar thermal CC theory for spin degrees of freedom. In this paper, we provide a formulation of our thermofield-inspired thermal CC for SU(2) systems. We apply the thermal CC to the Lipkin-Meshkov-Glick system as well as the one-dimensional transverse field Ising model as benchmark applications to highlight the accuracy of thermal CC in the study of finite-temperature phase diagrams in SU(2) systems.
American Physical Society