Precise measurement of the mass difference and the binding energy of hypertriton and antihypertriton

J. Adam,L. Adamczyk,J. Adams,J. K. Adkins,G. Agakishiev,M. M. Aggarwal,Z. Ahammed,I Alekseev,D. M. Anderson,R. Aoyama,A. Aparin,D. Arkhipkin,E. C. Aschenauer,M. U. Ashraf,F. Atetalla,A. Attri,G. S. Averichev,V. Bairathi,K. N. Barish,A. J. Bassill,Arabinda Behera,R. Bellwied,A. Bhasin,A. K. Bhati,J. Bielcik,J. Bielcikova,L. C. Bland,I. Bordyuzhin,J. D. Brandenburg,A. V. Brandin,J. Bryslawskyj,I. Bunzarov,J. M. Butterworth,H. Caines,M. Calderon De La Barca Sanchez,D. Cebra,I. Chakaberia,P. Chaloupka,B. K. Chan,F-H. Chang,Z. Chang,N. Chankova-Bunzarova,A. Chatterjee,S. Chattopadhyay,J. H. Chen,X. Chen,J. Cheng,M. Cherney,W. Christie,H. J. Crawford,M. Csanad,S. Das,T. G. Dedovich,I. M. Deppner,A. A. Derevschikov,L. Didenko,C. Dilks,X. Dong,J. L. Drachenberg,J. C. Dunlop,T Edmonds,N. Elsey,J. Engelage,G. Eppley,R. Esha,S. Esumi,O. Evdokimov,J. Ewigleben,O. Eyser,R. Fatemi,S. Fazio,P. Federic,J. Fedorisin,Y Feng,P. Filip,E. Finch,Y. Fisyak,L. Fulek,C. A. Gagliardi,T. Galatyuk,Frank Jm Geurts,A. Gibson,D. Grosnick,A. Gupta,W. Guryn,A. I. Hamad,A. Hamed,J. W. Harris,L. He,S. Heppelmann,N. Herrmann,L. Holub,Y Hong,S. Horvat,B. Huang,H. Z. Huang,S. L. Huang,T. Huang,X. Huang,T. J. Humanic,Peng Huo,G. Igo,W. W. Jacobs,A. Jentsch,Y. Ji,J. Jia,K. Jiang,S. Jowzaee,X. Ju,E. G. Judd,S. Kabana,S. Kagamaster,D. Kalinkin,K. Kang,D. Kapukchyan,K. Kauder,H. W. Ke,D. Keane,A. Kechechyan,M Kelsey,Y. V. Khyzhniak,D. P. Kikola,C. Kim,T. A. Kinghorn,I. Kisel,A. Kisiel,M. Kocan,L. Kochenda,L. K. Kosarzewski,L. Kramarik,P. Kravtsov,K. Krueger,N. Kulathunga Mudiyanselage,L. Kumar,R. Kunnawalkam Elayavalli,J. H. Kwasizur,R. Lacey,J. M. Landgraf,J. Lauret,A. Lebedev,R. Lednický,J. H. Lee,C. Li,W. D. Li,X. Li,Y. Li,Y. Liang,R Licenik,T. Lin,A. Lipiec,M. A. Lisa,F. Liu,H. Liu,P. Liu,T. Liu,X. Liu,Y. Liu,Z Liu,T. Ljubicic,W. J. Llope,M. Lomnitz,R. S. Longacre,S. Luo,X. Luo,G. L. Ma,L. Ma,R. Ma,Y. G. Ma,N. Magdy,R. Majka,D. Mallick,S. Margetis,C. Markert,H. S. Matis,O. Matonoha,J. Mazer,K. Meehan,J. C. Mei,N. G. Minaev,S. Mioduszewski,D. Mishra,B. Mohanty,M. M. Mondal,I. Mooney,Z. Moravcova,D. A. Morozov,Md. Nasim,K. Nayak,J. M. Nelson,D. B. Nemes,M. Nie,G. Nigmatkulov,T. Niida,L. V. Nogach,T. Nonaka,G. Odyniec,A. Ogawa,K. Oh,S. Oh,V. Okorokov,B. S. Page,R. Pak,Y. Panebratsev,B. Pawlik,D. Pawlowska,H. Pei,C. Perkins,Roland Laszlo Pinter,J. Pluta,J. Porter,M. Posik,N. K. Pruthi,M. Przybycien,J. Putschke,A. Quintero,Sooraj Krishnan Radhakrishnan,R. L. Ray,R. G. Reed,H. G. Ritter,Jay Roberts,O. V. Rogachevskiy,J. L. Romero,L. Ruan,J. Rusnak,O. Rusnakova,Niladribihari Sahoo,P. K. Sahu,S. Salur,J. Sandweiss,J. Schambach,W. B. Schmidke,N. Schmitz,B. R. Schweid,F. Seck,J. Seger,M. Sergeeva,R. Seto,P. Seyboth,N. Shah,E. Shahaliev,P. V. Shanmuganathan,M. Shao,F. Shen,W.Q. Shen,S. S. Shi,Q. Y. Shou,E. P. Sichtermann,S. Siejka,R. Sikora,M. Simko,J. B. Singh,S. Singha,D. Smirnov,N Smirnov,W. Solyst,P. Sorensen,H. M. Spinka,B. Srivastava,T. D. S. Stanislaus,M Stefaniak,D. J. Stewart,M. Strikhanov,B. Stringfellow,A. A. P. Suaide,T. Sugiura,M. Sumbera,B. Summa,X. M. Sun,Y. J. Sun,B. Surrow,D. N. Svirida,P. Szymanski,A. H. Tang,Z. Tang,A. Taranenko,T. Tarnowsky,J. H. Thomas,A. R. Timmins,D. Tlusty,T. Todoroki,M. Tokarev,C. A. Tomkiel,S. Trentalange,R. E. Tribble,P. Tribedy,S. K. Tripathy,O. D. Tsai,B. Tu,T. Ullrich,D. G. Underwood,I. Upsal,G. Van Buren,J. Vanek,A. N. Vasiliev,I. Vassiliev,F. Videbaek,S. Vokal,S. A. Voloshin,F. Wang,G. Wang,P. Wang,Y. Wang,J. C. Webb,L. Wen,G. D. Westfall,H. Wieman,S. W. Wissink,R. Witt,Y. Wu,Z. Xiao,G. Xie,W. Xie,H. Xu,N. Xu,Q. H. Xu,Y. Xu,Z. Xu,C. Yang,Q. Yang,S. Yang,Y. Yang,Z. Yang,Z. Ye,L. Yi,K. Yip,I. K. Yoo,H. Zbroszczyk,W. Zha,D Zhang,L. Zhang,S. Zhang,X. P. Zhang,Y. Zhang,Z. P. Zhang,J. Zhao,C. Zhong,C. Zhou,X. Zhu,Z. Zhu,M Zurek,M. Zyzak

Precise measurement of the mass difference and the binding energy of hypertriton and antihypertriton

2019

Using the STAR (Solenoidal Tracker At RHIC) detector at the Relativistic Heavy Ion Collider (RHIC), we have measured the $\Lambda$ hyperon binding energy $B_\Lambda$ for the hypertriton, which is the lightest hypernucleus yet discovered and consists of a proton, a neutron, and a $\Lambda$ hyperon. The measured $B_\Lambda$ differs from the widely used value and from predictions in which the hypertriton is modeled as a $\Lambda$ weakly bound to a deuterium nucleus. Our results place stringent constraints on the hyperon-nucleon interaction, and provide critical inputs for studying neutron star interiors, where strange matter may be present. The same data also permit more precise comparison between the masses of the hypertriton and the antihypertriton. Matter-antimatter symmetry pertaining to the binding of strange and antistrange quarks in a nucleus is thus tested quantitatively for the first time. No deviation from the expected exact symmetry is observed.

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