利用α关联衰变链鉴别新同位素265107Bh

主要介绍了合成和鉴别107号元素的新同位素265Bh的实验装置、实验方法以及实验结果.目标核265Bh是由能量为135MeV的26Mg离子轰击243Am靶,通过融合蒸发反应而产生. 反应产物首先由He-jet系统传输到装有数个探测器对的转轮收集测量系统，然后依靠母子核遗传关系通过观察新同位素和它们已知子核261Db和257Lr之间的a衰变的关联，来实现对新核素的鉴别. 实验测得265Bh的a衰变能量为(9.24±0.05)MeV, 半衰期为0.94＋0.70 -0.31s. 从该实验得出的265Bh的a衰变能量和半寿命能够与理论预言一致.     

265Bh(Z=107)同位素的首次观测

在兰州的重离子加速器上用²⁶Mg离子束轰击²⁴³Am靶,产生了新同位素²⁶⁵Bh.通过观测新同位素²⁶⁵Bh和它的已知子核²⁶¹Db和²⁵⁷Lr之间的α衰变的关联,实现了对新核素的鉴别.实验中使用了一套新建立的具有数个探测器对的转轮收集探测系统.将该系统用于特殊的母–子核搜索模式,从而大大减少了本底.共测得了8个²⁶⁵Bh的α衰变关联事件;同时4个已知核²⁶⁴Bh的衰变关联事件也被鉴别出来.实验测得²⁶⁵Bh的α衰变能量为(9.24±0.05)MeV,半衰期为0.94+0.70–0.31s.     

利用α关联衰变链鉴别新同位素_(107)~(265)Bh

主要介绍了合成和鉴别107号元素的新同位素265Bh的实验装置、实验方法以及实验结果.目标核265Bh是由能量为135MeV的26Mg离子轰击243Am靶,通过融合蒸发反应而产生.反应产物首先由He jet系统传输到装有数个探测器对的转轮收集测量系统,然后依靠母子核遗传关系通过观察新同位素和它们已知子核261Db和257Lr之间的α衰变的关联,来实现对新核素的鉴别.实验测得265Bh的α衰变能量为(9.24±0.05)MeV, 半衰期为0.94+0.70-0.31s.从该实验得出的265Bh的α衰变能量和半寿命能够与理论预言一致.     

Development of front-end readout electronics for silicon strip detectors

Front-end readout electronics have been developed for silicon strip detectors at our institute. In this system an Application Specific Integrated Circuit (ASIC) ATHED is used to realize multi-channel energy and time measurements. The slow control of ASIC chips is achieved by parallel port and the timing control signals of ASIC chips are implemented with the CPLD. The data acquisition is carried out with a PXI-DAQ card. The software has a user-friendly GUI developed with LabWindows/CVI in the Windows XP operating system. The test results show that the energy resolution is about 1.14% for alpha at 5.48 MeV and the maximum channel crosstalk of the system is 4.60%. The performance of the system is very reliable and is suitable for nuclear physics experiments.     

一种新型低噪声大动态范围小型前端电路的研制

设计了一款小型化、低噪声、大动态范围的前端处理电路,包括电荷灵敏前放、成形放大电路、单道脉冲幅度分析电路。前放的等效输入噪声≤1.5 keV,动态范围可达0~11 V,积分非线性 ≤0.11%。该电路为模块化电路,当前放与主放模块构成系统时,其分辨可以达到0.12%。当前放、主放模块与中国科学院近代物理研究所制作的离子注入型硅探测器构成系统时,采用239Pu 源进行测试,测得在5.157 MeV时的能量分辨约为0.82%;当主放、单道脉冲幅度分析模块与中国科学院近代物理研究所制作的碘化铯晶体探测器构成系统时,采用60Co 源进行测试,对于能量为1.332 MeV 的 射线,测得其能量分辨约为7.9%。该电路可用于半导体探测器、光电倍增管及电子倍增器等探测器信号的处理。目前,小型前端电路已经应用于中国科学院近代物理研究所自行研制的便携式盐湖卤水铀、钍、钾快速测量仪的原型样机,达到了预期效果。A small dimension front-end circuit with low noise and wide output dynamic range is introduced in this paper. The front-end circuit is made up of a charge sensitive preamplifier, a shaping circuit and a single channel pulse height analyzer. The equivalent input noise is under 1.5 keV. The output integral nonlinearity is less than 0.11% within the dynamic range of 011 V. And the circuit can be suitable for different conditions by different modules. The resolution was about 0.12% with the charge sensitive preamplifier and the main amplifier. The energy resolution of 0.82% was achieved for 5.157 MeV -rays from a 239Pu source with the charge sensitive preamplifier, the main amplifier and anion-injection silicon detector designed by the Institute of Modern Physics(IMP). An energy resolution of 7.9% was achieved for 1.332 MeV rays from a stationary 60Co source with the main amplifier, the single channel pulse height analyzer and a CsI scintillator detector designed by the IMP. The front-end circuit has the features of wide output dynamic range, simple structure, high level of integration,small dimensions, low noise, fast rise time of the output pulse and excellent stability. The front-end circuit can be applied to signal processing of semiconductor detectors, photomultiplier tubes and electrons multiplier. And the front-end circuit had been applied to a prototype of the portable rapid measuring instrument designed by IMP for measuring Uranium, Thorium and Potassium in the salt lake brine with goodtest result.     

新同位素265Bh(Z=107)的合成证据

利用兰州重离子加速器提供的26Mg离子束轰击243Am靶, 产生了新同位素265Bh.实验中用氦喷技术对产物进行传输, 并用一套具有数对探测器组的转轮收集探测系统对产物进行收集和测量.通过观测265Bh与它的衰变子核261Db及257Lr之间的α衰变的关联, 实现了对新核素的鉴别.实验测得265Bh的α衰变能量为(9.24±0.05) MeV, 半衰期为0.94+0.70 -0.31 s.     

对69Krβ延迟质子衰变的观察

通过对³²S+Ca反应中衰变质子谱的观测,发现了一组新的质子谱线,其能量为(4.07±0.05)MeV,对应的衰期为(32±10)ms,经反应道分析及与理论预言比较,确定该质子活性来源于⁴⁰Ca(³²S,3n)反应产生的⁶⁹Kr的β延迟质子衰变,它相应于由⁶⁹Br中的T=3/2同位旋相似态到⁶⁸Se基态的质子跃迁.基于测量结果与库仑位移能计算,得到⁶⁹Kr的质量剩余为(－32.15±0.30)MeV,并提出了⁶⁹Kr的部分衰变纲图.