C. Drischler, Sophia Han, J. Lattimer, M. Prakash, S. Reddy, Tianqi Zhao
{"title":"Limiting masses and radii of neutron stars and their implications","authors":"C. Drischler, Sophia Han, J. Lattimer, M. Prakash, S. Reddy, Tianqi Zhao","doi":"10.1103/PHYSREVC.103.045808","DOIUrl":null,"url":null,"abstract":"We combine equation of state of dense matter up to twice nuclear saturation density ($n_{\\rm sat}=0.16\\, \\text{fm}^{-3}$) obtained using chiral effective field theory ($\\chi$EFT), and recent observations of neutron stars to gain insights about the high-density matter encountered in their cores. A key element in our study is the recent Bayesian analysis of correlated EFT truncation errors based on order-by-order calculations up to next-to-next-to-next-to-leading order in the $\\chi$EFT expansion. We refine the bounds on the maximum mass imposed by causality at high densities, and provide stringent limits on the maximum and minimum radii of $\\sim1.4\\,{\\rm M}_{\\odot}$ and $\\sim2.0\\,{\\rm M}_{\\odot}$ stars. Including $\\chi$EFT predictions from $n_{\\rm sat}$ to $2\\,n_{\\rm sat}$ reduces the permitted ranges of the radius of a $1.4\\,{\\rm M}_{\\odot}$ star, $R_{1.4}$, by $\\sim3.5\\, \\text{km}$. If observations indicate $R_{1.4} 1/2$ for densities above $2\\,n_{\\rm sat}$, or that $\\chi$EFT breaks down below $2\\,n_{\\rm sat}$. We also comment on the nature of the secondary compact object in GW190814 with mass $\\simeq 2.6\\,{\\rm M}_{\\odot}$, and discuss the implications of massive neutron stars $>2.1 \\,{\\rm M}_{\\odot}\\,(2.6\\,{\\rm M}_{\\odot})$ in future radio and gravitational-wave searches. Some form of strongly interacting matter with $c^2_{s}>0.35\\, (0.55)$ must be realized in the cores of such massive neutron stars. In the absence of phase transitions below $2\\,n_{\\rm sat}$, the small tidal deformability inferred from GW170817 lends support for the relatively small pressure predicted by $\\chi$EFT for the baryon density $n_{\\rm B}$ in the range $1-2\\,n_{\\rm sat}$. Together they imply that the rapid stiffening required to support a high maximum mass should occur only when $n_{\\rm B} \\gtrsim 1.5-1.8\\,n_{\\rm sat}$.","PeriodicalId":8463,"journal":{"name":"arXiv: Nuclear Theory","volume":"81 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2020-09-14","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"36","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"arXiv: Nuclear Theory","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1103/PHYSREVC.103.045808","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 36
Abstract
We combine equation of state of dense matter up to twice nuclear saturation density ($n_{\rm sat}=0.16\, \text{fm}^{-3}$) obtained using chiral effective field theory ($\chi$EFT), and recent observations of neutron stars to gain insights about the high-density matter encountered in their cores. A key element in our study is the recent Bayesian analysis of correlated EFT truncation errors based on order-by-order calculations up to next-to-next-to-next-to-leading order in the $\chi$EFT expansion. We refine the bounds on the maximum mass imposed by causality at high densities, and provide stringent limits on the maximum and minimum radii of $\sim1.4\,{\rm M}_{\odot}$ and $\sim2.0\,{\rm M}_{\odot}$ stars. Including $\chi$EFT predictions from $n_{\rm sat}$ to $2\,n_{\rm sat}$ reduces the permitted ranges of the radius of a $1.4\,{\rm M}_{\odot}$ star, $R_{1.4}$, by $\sim3.5\, \text{km}$. If observations indicate $R_{1.4} 1/2$ for densities above $2\,n_{\rm sat}$, or that $\chi$EFT breaks down below $2\,n_{\rm sat}$. We also comment on the nature of the secondary compact object in GW190814 with mass $\simeq 2.6\,{\rm M}_{\odot}$, and discuss the implications of massive neutron stars $>2.1 \,{\rm M}_{\odot}\,(2.6\,{\rm M}_{\odot})$ in future radio and gravitational-wave searches. Some form of strongly interacting matter with $c^2_{s}>0.35\, (0.55)$ must be realized in the cores of such massive neutron stars. In the absence of phase transitions below $2\,n_{\rm sat}$, the small tidal deformability inferred from GW170817 lends support for the relatively small pressure predicted by $\chi$EFT for the baryon density $n_{\rm B}$ in the range $1-2\,n_{\rm sat}$. Together they imply that the rapid stiffening required to support a high maximum mass should occur only when $n_{\rm B} \gtrsim 1.5-1.8\,n_{\rm sat}$.