缺中子核素~(101)In低位同核异能态的首次观测
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摘要
在兰州重离子加速器冷却储存环(HIRFL-CSR)上,用初级束流112Sn35+轰击了靶厚约10 mm的Be靶,产生了101In的基态和低位同核异能态。这些实验产生的碎片每25 s经过放射性束流线RIBLL2的筛选后注入到实验环CSRe中,利用飞行时间探测器测量离子在CSRe中的回旋周期。在此次实验中,磁场晃动会导致离子在环内的循环周期发生改变,传统的离子鉴别方法难以完成大部分离子的鉴别。通过发展和运用单次注入离子鉴别这一新的离子鉴别方法,有效地消除了磁场晃动对于离子鉴别的影响,并清楚地将101In基态和低位同核异能态鉴别出来,从而首次在实验中观测到101In的低位同核异能态。实验得到的激发能与理论外推值在112 keV的误差范围内一致,其低位同核异能态的寿命大于200μs。
Isochronous mass spectrometry has been applied to112 Sn projectile fragments at the HIRFL-CSR facility in Lanzhou. To produce short-lived nuclei of interest, we used projectile fragmentation of112 Sn35+primary beams in a ~10 mm thick9 Be production target. The fragments were selected and analyzed by RIBLL2 and injected into the experimental storage ring(CSRe) every 25 s. To measure revolution times of stored ions,we used a Time-Of-Flight detector installed in CSRe. A new particle identification method was developed to distinguish ions on the measured revolution time spectrum for each injection. Based on this method, the shifts of the revolution time due to instable dipole magnet fields can be corrected and the ground and isomeric states of101 In have been well-resolved. The measured excitation energy is consistent with the theoretical value in the error range of 112 keV. The lifetime of the isomeric states of101 In is more than 200 μs.
Isochronous mass spectrometry has been applied to112 Sn projectile fragments at the HIRFL-CSR facility in Lanzhou. To produce short-lived nuclei of interest, we used projectile fragmentation of112 Sn35+primary beams in a ~10 mm thick9 Be production target. The fragments were selected and analyzed by RIBLL2 and injected into the experimental storage ring(CSRe) every 25 s. To measure revolution times of stored ions,we used a Time-Of-Flight detector installed in CSRe. A new particle identification method was developed to distinguish ions on the measured revolution time spectrum for each injection. Based on this method, the shifts of the revolution time due to instable dipole magnet fields can be corrected and the ground and isomeric states of101 In have been well-resolved. The measured excitation energy is consistent with the theoretical value in the error range of 112 keV. The lifetime of the isomeric states of101 In is more than 200 μs.
引文
[1]HUYSE M,MARMOL P DEL,COENEN E,et al.Z Phys A,1988,330:121.
[2]XU Hushan,ZHOU Xiaohong,XIAO Guoqing,et al.Nuclear Physics Review,2003,20(2):76.(in Chinese)(徐瑚珊,周小红,肖国青,等.原子核物理评论,2003,20(2):76.)
[3]XIE Xiujun,MU Wantong,SUN Xiurong,et al.Atomic Energy Science and Technology,1985,19(4):0476.(in Chinese)(谢秀君,牟万统,孙秀荣,等.原子能科学技术,1985,19(4):476.)
[4]HE Ming,JIANG Shan,JIANG Songsheng,et al.Atomic Energy Science and Technology,1999,33(2):34.(in Chinese)(何明,姜山,蒋崧生,等.原子能科学技术,1999,33(2):34.)
[5]SUN B H,GEISSEL H,HAUSMANN H,et al.Chin Phys C,2009,33(S1):161.
[6]TU X L,XU H S,WANG M,et al.Nucl Instr and Meth A,2011,654:613.
[7]XIA Jiawen,ZHAN Wenlong,WEI Baowen,et al.High Power Laser And Particle Beams,2008,20(11):1787.(in Chinese)(夏佳文,詹文龙,魏宝文,等.强激光与粒子束,2008,20(11):1787.)
[8]LIU Dawei,WANG Meng,XU Xing,et al.Nuclear Physics Review,2016,33(3):302.(in Chinese)(刘大委,王猛,徐星,等.原子核物理评论,2016,33(3):302.)
[9]MEI B,TU X L,WAMG M,et al.Nucl Instr Meth A,2010,624:109.
[10]ZENG Qi,WANG Meng,ZHANG Yuhu,et al.Nuclear Physics Review,2017,34(3):414.(in Chinese)(曾奇,王猛,张玉虎,等.原子核物理评论,2017,34(3):414.)
[11]ZHANG Yuhu,WANG Meng,Yu A Litvinov,et al.Nuclear Physics Review,2016,33(2):122.
[12]XU X,ZHANG P,SHUAI P,et al.Phys Rev Lett,2016,117:1082503.
[13]ZHANG Y H,XU H S,LITVINOV Y A,et al.Phys Rev Lett,2012,109:102501.
[14]ZHU Yongsheng.Probability and Statistics in Experimental Physics[M].Beijing:Sicence Press,2006:303.(in Chinese)(朱永生.实验物理中的概率和统计[M].北京:科学出版社,2006:303.)
[15]TARASOV O B,BAZIN D,et al.Nucl Instrum Meth B,2008,266(19-20):4657.
[16]AUDI G,Kondev F G,WANG M,et al.Chin Phys C,2017,44(3):30002.
[17]SHUAI Peng,TU Xiaolin,ZHANG Yuhu,et al.Nuclear Physics Review,2016,33(2):173.(in Chinese)(帅鹏,涂小林,张玉虎,等.原子核物理评论,2016,33(2):173.)
[2]XU Hushan,ZHOU Xiaohong,XIAO Guoqing,et al.Nuclear Physics Review,2003,20(2):76.(in Chinese)(徐瑚珊,周小红,肖国青,等.原子核物理评论,2003,20(2):76.)
[3]XIE Xiujun,MU Wantong,SUN Xiurong,et al.Atomic Energy Science and Technology,1985,19(4):0476.(in Chinese)(谢秀君,牟万统,孙秀荣,等.原子能科学技术,1985,19(4):476.)
[4]HE Ming,JIANG Shan,JIANG Songsheng,et al.Atomic Energy Science and Technology,1999,33(2):34.(in Chinese)(何明,姜山,蒋崧生,等.原子能科学技术,1999,33(2):34.)
[5]SUN B H,GEISSEL H,HAUSMANN H,et al.Chin Phys C,2009,33(S1):161.
[6]TU X L,XU H S,WANG M,et al.Nucl Instr and Meth A,2011,654:613.
[7]XIA Jiawen,ZHAN Wenlong,WEI Baowen,et al.High Power Laser And Particle Beams,2008,20(11):1787.(in Chinese)(夏佳文,詹文龙,魏宝文,等.强激光与粒子束,2008,20(11):1787.)
[8]LIU Dawei,WANG Meng,XU Xing,et al.Nuclear Physics Review,2016,33(3):302.(in Chinese)(刘大委,王猛,徐星,等.原子核物理评论,2016,33(3):302.)
[9]MEI B,TU X L,WAMG M,et al.Nucl Instr Meth A,2010,624:109.
[10]ZENG Qi,WANG Meng,ZHANG Yuhu,et al.Nuclear Physics Review,2017,34(3):414.(in Chinese)(曾奇,王猛,张玉虎,等.原子核物理评论,2017,34(3):414.)
[11]ZHANG Yuhu,WANG Meng,Yu A Litvinov,et al.Nuclear Physics Review,2016,33(2):122.
[12]XU X,ZHANG P,SHUAI P,et al.Phys Rev Lett,2016,117:1082503.
[13]ZHANG Y H,XU H S,LITVINOV Y A,et al.Phys Rev Lett,2012,109:102501.
[14]ZHU Yongsheng.Probability and Statistics in Experimental Physics[M].Beijing:Sicence Press,2006:303.(in Chinese)(朱永生.实验物理中的概率和统计[M].北京:科学出版社,2006:303.)
[15]TARASOV O B,BAZIN D,et al.Nucl Instrum Meth B,2008,266(19-20):4657.
[16]AUDI G,Kondev F G,WANG M,et al.Chin Phys C,2017,44(3):30002.
[17]SHUAI Peng,TU Xiaolin,ZHANG Yuhu,et al.Nuclear Physics Review,2016,33(2):173.(in Chinese)(帅鹏,涂小林,张玉虎,等.原子核物理评论,2016,33(2):173.)