Authors
Bao-An Li
Published in
Physical review letters. Volume 136. Issue 24. Pages 242301. Jun 19, 2026.
Abstract
The trace anomaly of dense matter, Δ≡1/3-P/ϵ, defined through the ratio w≡P/ϵ of pressure P to energy density ϵ, quantifies deviations from conformal symmetry and provides a dimensionless measure of the stiffness of the equation of state (EOS) relevant for both neutron stars and heavy-ion collisions. While Δ(ϵ) has recently been inferred from neutron star observations, we report the first Bayesian extraction of the trace anomaly from collective flow observables in intermediate-energy heavy-ion collisions. By employing transport-model simulations that explicitly decouple the cold matter mean-field potential from thermal effects, we directly constrain the EOS of cold dense matter. Remarkably, the trace anomaly inferred from laboratory flow data agrees quantitatively, within 68% credible intervals, with independent astrophysical posterior bands. This nontrivial agreement demonstrates that heavy-ion collisions and neutron star observations probe the same macroscopic properties in a mutually consistent way, establishing the dense-matter trace anomaly as a composition-insensitive macroscopic bridge observable across widely different physical environments.
PMID:
42412462
Bibliographic data and abstract were imported from PubMed on 07 Jul 2026.
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