Improved structure of calcium isotopes from ab initio calculations
Abstract: The in-medium similarity renormalization group (IMSRG) is a powerful and flexible many-body method to compute the structure of nuclei starting from nuclear forces. Recent developments have extended the IMSRG from its standard truncation at the normal-ordered two-body level, the IMSRG(2), to a precision approximation including normal-ordered three-body operators, the IMSRG(3)-$N7$. This improvement provides a more precise solution to the many-body problem and makes it possible to quantify many-body uncertainties in IMSRG calculations. We explore the structure of ${44,48,52}$Ca using the IMSRG(3)-$N7$, focusing on understanding existing discrepancies of the IMSRG(2) to experimental results. We find a significantly better description of the first $2+$ excitation energy of ${48}$Ca, improving the description of the shell closure at $N=28$. At the same time, we find that the IMSRG(3)-$N7$ corrections to charge radii do not resolve the systematic underprediction of the puzzling large charge radius difference between ${52}$Ca and ${48}$Ca. We present estimates of many-body uncertainties of IMSRG(2) calculations applicable also to other systems based on the size extensivity of the method.
Paper Prompts
Sign up for free to create and run prompts on this paper using GPT-5.
Top Community Prompts
Collections
Sign up for free to add this paper to one or more collections.