Jirina Stone

Dense matter in neutron stars with eXTP

Science China Physics, Mechanics & Astronomy Springer Nature 68:11 (2025) 119503

Authors:

Ang Li, Anna L Watts, Guobao Zhang, Sebastien Guillot, Yanjun Xu, Andrea Santangelo, Silvia Zane, Hua Feng, Shuang-Nan Zhang, Mingyu Ge, Liqiang Qi, Tuomo Salmi, Bas Dorsman, Zhiqiang Miao, Zhonghao Tu, Yuri Cavecchi, Xia Zhou, Xiaoping Zheng, Weihua Wang, Quan Cheng, Xuezhi Liu, Yining Wei, Wei Wang, Yujing Xu, Shanshan Weng, Weiwei Zhu, Zhaosheng Li, Lijing Shao, Youli Tuo, Akira Dohi, Ming Lyu, Peng Liu, Jianping Yuan, Mingyang Wang, Wenda Zhang, Zexi Li, Lian Tao, Liang Zhang, Hong Shen, Constança Providência, Laura Tolos, Alessandro Patruno, Li Li, Guozhu Liu, Kai Zhou, Lie-Wen Chen, Yizhong Fan, Toshitaka Kajino, Dong Lai, Xiangdong Li, Jie Meng, Xiaodong Tang, Zhigang Xiao, Shaolin Xiong, Renxin Xu, Shan-Gui Zhou, David R Ballantyne, G Fiorella Burgio, Jérôme Chenevez, Devarshi Choudhury, Anthea F Fantina, Duncan K Galloway, Francesca Gulminelli, Kai Hebeler, Mariska Hoogkamer, Jorge E Horvath, Yves Kini, Aleksi Kurkela, Manuel Linares, Jérôme Margueron, Melissa Mendes, Micaela Oertel, Alessandro Papitto, Juri Poutanen, Nanda Rea, Achim Schwenk, Xin-Ying Song, Isak Svensson, David Tsang, Aleksi Vuorinen, Nils Andersson, M Coleman Miller, Luciano Rezzolla, Jirina R Stone, Anthony W Thomas

Abstract:

In this white paper, we present the potential of the enhanced X-ray timing and polarimetry (eXTP) mission to constrain the equation of state of dense matter in neutron stars, exploring regimes not directly accessible to terrestrial experiments. By observing a diverse population of neutron stars—including isolated objects, X-ray bursters, and accreting systems—eXTP’s unique combination of timing, spectroscopy, and polarimetry enables high-precision measurements of compactness, spin, surface temperature, polarimetric signals, and timing irregularity. These multifaceted observations, combined with advances in theoretical modeling, pave the way toward a comprehensive description of the properties and phases of dense matter from the crust to the core of neutron stars. Under development by an international Consortium led by the Institute of High Energy Physics of the Chinese Academy of Sciences, the eXTP mission is planned to be launched in early 2030.

Nuclear Symmetry Energy in Strongly Interacting Matter: Past, Present and Future

Symmetry MDPI 16:8 (2024) 1038

Abstract:

The concept of symmetry under various transformations of quantities describing basic natural phenomena is one of the fundamental principles in the mathematical formulation of physical laws. Starting with Noether’s theorems, we highlight some well–known examples of global symmetries and symmetry breaking on the particle level, such as the separation of strong and electroweak interactions and the Higgs mechanism, which gives mass to leptons and quarks. The relation between symmetry energy and charge symmetry breaking at both the nuclear level (under the interchange of protons and neutrons) and the particle level (under the interchange of u and d quarks) forms the main subject of this work. We trace the concept of symmetry energy from its introduction in the simple semi-empirical mass formula and liquid drop models to the most sophisticated non-relativistic, relativistic, and ab initio models. Methods used to extract symmetry energy attributes, utilizing the most significant combined terrestrial and astrophysical data and theoretical predictions, are reviewed. This includes properties of finite nuclei, heavy-ion collisions, neutron stars, gravitational waves, and parity–violating electron scattering experiments such as CREX and PREX, for which selected examples are provided. Finally, future approaches to investigation of the symmetry energy and its properties are discussed.

Hartree-Fock formulation of the QMC model at finite temperature

Physical Review D American Physical Society (APS) 109:8 (2024) 083035

Authors:

PAM Guichon, JR Stone, AW Thomas

Proton and neutron density distributions at supranormal density in low- and medium-energy heavy-ion collisions. II. Central Pb + Pb collisions

Physical Review C American Physical Society (APS) 109:4 (2024) 044603

Authors:

JR Stone, P Danielewicz, Y Iwata

Coulomb and symmetry-energy effects on proton and neutron density-distributions in central heavy-ion collisions, across beam energies and system masses

EPJ Web of Conferences EDP Sciences 306 (2024) 01031

Authors:

Jirina R Stone, Pawel Danielewicz, Yoritaka Iwata