Coulomb dissociation ofN20,21

M Röder ,M Freudenberger,J Kurcewicz,Simon Lindberg,G Burgunder,F Farinon,J S Winfield,J Van De Walle,G Ickert,M Barr,C Caesar ,A Heinz ,O Sorlin ,D Rossi ,P Velho ,M Holl ,Juan Alcántara ,M Heil ,C Rigollet ,K Göbel ,T Aumann ,J T Taylor ,J Marganiec ,T Heftrich ,M Weigand ,Victor Stoica ,J Hagdahl ,T Kröll ,H Álvarez‐Pol ,S Beceiro ,L M Fraile ,A Movsesyan ,D Galaviz ,W N Catford ,B Jonson ,D Savran ,O Tengblad ,C A Bertulani ,R Plag ,R Gernhäuser ,A Wagner ,A Zilges ,T Le Bleis ,R Knöbel ,T Nilsson ,A Henriques ,M Caamaño ,I Dillmann ,H Johansson ,L V Chulkov ,María José García Borge ,A Kelić-Heil ,P J Woods ,N Kalantar‐Nayestanaki ,P Diaz Fernandez ,C Langer ,J Machado ,H Geißel ,G L Wilson ,E Casarejos ,Christian Wimmer ,C Wheldon ,O Ershova ,Á Perea ,T Adachi ,R C Lemmon ,S Piétri ,R Krücken ,Y Aksyutina ,H Weick ,J Benlliure ,J Sanchez Del Rio Saez ,Bijan Najafi ,D Bemmerer ,N I Ashwood ,J Cederkäll ,D Cortina-Gil ,E Uberseder ,J Enders ,A Ignatov ,F Wamers ,D Yakorev ,P Golubev ,H Scheit ,H Simon ,R Kanungo ,Z Elekes ,S Altstadt ,V Panin ,Y Togano ,M V Zhukov ,R Reifarth ,B Štreicher ,L Atar ,A Procházka ,G Rastrepina ,V.v Avdeichikov ,D González-Díaz ,O Lepyoshkina ,R Thies ,U Datta Pramanik ,K Riisager ,C Nociforo ,M Petri ,M Labiche ,M Mostazo ,M Chartier ,B Jakobsson ,A Estradé ,Sovan Chakraborty ,Hafizur Rahaman ,G Ribeiro ,M V Ricciardi ,H O U Fynbo ,N Kurz ,M Freer ,В А Волков ,R Crespo ,M Heine ,K Boretzky ,S Terashima ,S Paschalis ,Κ Zuber

doi:10.1103/physrevc.93.065807

Abstract

Neutron-rich light nuclei and their reactions play an important role for the creation of chemical elements. Here, data from a Coulomb dissociation experiment on $^{20,21}$N are reported. Relativistic $^{20,21}$N ions impinged on a lead target and the Coulomb dissociation cross section was determined in a kinematically complete experiment. Using the detailed balance theorem, the $^{19}\mathrm{N}(\mathrm{n},\gamma)^{20}\mathrm{N}$ and $^{20}\mathrm{N}(\mathrm{n},\gamma)^{21}\mathrm{N}$ excitation functions and thermonuclear reaction rates have been determined. The $^{19}\mathrm{N}(\mathrm{n},\gamma)^{20}\mathrm{N}$ rate is up to a factor of 5 higher at $T<1$\,GK with respect to previous theoretical calculations, leading to a 10\,\% decrease in the predicted fluorine abundance.

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