Probing the Symmetry Energy with the Spectral Pion Ratio.

J. Estee,W. G. Lynch,C.Y. Tsang,J. Barney,G. Jhang,M. B. Tsang,R. Wang,M. Kaneko,J.W. Lee,Tadaaki Isobe,M. Kurata-Nishimura,T. Murakami,D. S. Ahn,L. Atar,Thomas Aumann,H. Baba,K. Boretzky,J. Brzychczyk,G. Cerizza,Nobuyuki Chiga,N. Fukuda,I. Gasparic,B. Hong,A. Horvat,Kazuo Ieki,N. Inabe,Y. J. Kim,Toshimitsu Kobayashi,Yosuke Kondo,P. Lasko,H. S. Lee,Y. Leifels,J. Łukasik,J. Manfredi,Alan McIntosh,P. Morfouace,Takashi Nakamura,Noritsugu Nakatsuka,S. Nishimura,Hideaki Otsu,Piotr Pawłowski,K. Pelczar,D. Rossi,Hiroyoshi Sakurai,C. Santamaria,H. Sato,H. Scheit,Rebecca Shane,Yohei Shimizu,H. Simon,A. Snoch,A. Sochocka,Toshiyuki Sumikama,H. Suzuki,D Suzuki,Hiroyuki Takeda,S. Tangwancharoen,H. Toernqvist,Yasuhiro Togano,Zhigang Xiao,Sherry Yennello,Yingxun Zhang,M.D. Cozma

Probing the Symmetry Energy with the Spectral Pion Ratio.

2021

Many neutron star (NS) properties, such as the proton fraction within a NS, reflect the symmetry energy contributions to the Equation of State that dominate when neutron and proton densities differ strongly. To constrain these contributions at supra-saturation densities, we measure the spectra of charged pions produced by colliding rare isotope tin (Sn) beams with isotopically enriched Sn targets. Using ratios of the charged pion spectra measured at high transverse momenta, we deduce the slope of the symmetry energy to be $42 < L < 117$ MeV. This value is slightly lower but consistent with the $L$ values deduced from a recent measurement of the neutron skin thickness of $^{208}$Pb.

Keywords:

Equation of state
Nuclear physics
Proton
Tin
Spectral line
Physics
Pion
Isotope
Neutron star
Neutron

Correction
Source
Cite
Save
Machine Reading By IdeaReader

References

Citations