Summerlee Science Complex Room 1305
MSc Candidate
Ryan Curry
Abstract
We investigate the nuclear many-body problem through two distinct projects. In the first, we develop a novel method for calculating the second-order perturbation theory correction to the ground state energy of a nuclear-many system in a continuum Quantum Monte Carlo calculation. Second-order (and higher) perturbative corrections are very difficult to calculate in most ab initio many-body methods since they are usually concerned with calculating only the ground state energy. By introducing a new method that maps the calculation of the second-order correction to an evolution in imaginary time using Diffusion Monte Carlo, we are able to calculate these terms for the first time in a continuum nuclear context. We complete benchmarking calculations in the two-body sector, as well as for interactions that break charge independence in the nuclear Hamiltonian. We then employ our new method to investigate the many-body perturbativeness of modern nuclear interactions derived from chiral effective field theory. We find that in certain regimes the interactions are not entirely perturbative, which could have important implications for nuclear physics. In the second project, we change tactics and approach the nuclear many-body problem within a lattice formalism. We apply a lattice based Auxiliary Field Quantum Monte Carlo approach that is used widely for the study of condensed matter systems, and modify it in order to study nuclear systems. This work serves as the foundation for building an ongoing nuclear physics research program using lattice quantum Monte Carlo.
Examination Committee
- Dr. Eric Poisson, Chair
- Dr: Alexandros Gezerlis, Advisor
- Dr. Paul Garrett, Advisory Committee
- Dr. Robert Wickham, Graduate Faculty