Saved in:
Bibliographic Details
Main Authors: Margueron, J., Khan, E.
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.12456
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866910051479846912
author Margueron, J.
Khan, E.
author_facet Margueron, J.
Khan, E.
contents The most accurate approach to determine the compressibility of nuclear matter remains the one based on microscopic Energy Density Functionals (EDFs). Recent analyses yield a value for nuclear incompressibility modulus $K_\sat=240\pm 20$~MeV, defined in nuclear matter as the second derivative of the energy per particle at saturation density. However, we demonstrate that the compressibility modulus can be reduced to values shifted by four times the suggested uncertainty, i.e., $K_\sat\approx 160$~MeV, by providing examples based on models where the second derivative ($K_\sat$) and third derivative ($Q_\sat$) of the energy per particle at saturation density can be independently varied, while the experimental binding energies, charge radii, and ISGMR data in $^{120}$Sn and $^{208}$Pb are enforced. The present work suggests a new methodology to access the compressibility of nuclear matter from nuclear experiments, still based on microscopic models, but using EDFs containing more flexibility than the ones employed up to now. Consequences of our results for nuclear matter at supra-saturation density are also discussed by exploring the quarkyonic cross-over. We predict that, for our models with low values for $K_\sat$, the quark onset density has to be low for neutron stars to exist.
format Preprint
id arxiv_https___arxiv_org_abs_2603_12456
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle How well known is the compressibility of nuclear matter?
Margueron, J.
Khan, E.
Nuclear Theory
The most accurate approach to determine the compressibility of nuclear matter remains the one based on microscopic Energy Density Functionals (EDFs). Recent analyses yield a value for nuclear incompressibility modulus $K_\sat=240\pm 20$~MeV, defined in nuclear matter as the second derivative of the energy per particle at saturation density. However, we demonstrate that the compressibility modulus can be reduced to values shifted by four times the suggested uncertainty, i.e., $K_\sat\approx 160$~MeV, by providing examples based on models where the second derivative ($K_\sat$) and third derivative ($Q_\sat$) of the energy per particle at saturation density can be independently varied, while the experimental binding energies, charge radii, and ISGMR data in $^{120}$Sn and $^{208}$Pb are enforced. The present work suggests a new methodology to access the compressibility of nuclear matter from nuclear experiments, still based on microscopic models, but using EDFs containing more flexibility than the ones employed up to now. Consequences of our results for nuclear matter at supra-saturation density are also discussed by exploring the quarkyonic cross-over. We predict that, for our models with low values for $K_\sat$, the quark onset density has to be low for neutron stars to exist.
title How well known is the compressibility of nuclear matter?
topic Nuclear Theory
url https://arxiv.org/abs/2603.12456