排序方式: 共有30条查询结果,搜索用时 218 毫秒
1.
利用120MeV的22Ne离子束轰击241Am靶,通过241Am(22Ne,4n)259Db反应合成了一个Z=105,质量数为259的新同位素.反应产物是用氦喷嘴技术和转动轮装置传输收集的.借助一系列金硅面垒探测器探测到了反应产物及其子核的α衰变.新同位素的原子序数Z和质量数A是借助该同位素和已知的255Lr核之间的遗传关系得到了确定的鉴别.新同位素259Db的测量半衰期为(0.51±0.16)s;它的α粒子能量为9.47MeV.由本实验导出的259Db的Qα值同理论预言结果能够较好地符合. 相似文献
2.
3.
4.
5.
197Au were irradiated with 47 MeV/u 12C ions. Iridium was produced via the multinucleon transfer reactions in bombardments of 197Au with 12C. and was separated radiochemically from Au and the mixture of the reaction products. The γ radioactivities of Ir isotopes were measured by using a HPGe detector. The production cross sections of Ir isotopes were determined from activities of Ir isotopes at the end of bombardment and the other relative data. It has been found that the cross sections for neutron-rich isotopes of iridium show an exponential dependence on the values of Qgg. Our experimental results also demonstrate lack of correlation between the cross sections and Qgg in the case of neutron-deficient isotopes of iridium. The fact can be explained from that neutron-rich isotopes of iridium were produced in the deep inelastic transfer reactions. 相似文献
6.
徐岩冰 周小红 宋立涛 郭应祥 孙志宇 M.Oshima T.Toh A.Osa M.Koizumi J.Katakura Y.Hatsukawa M.Matsuda M.Sugawara 《中国物理 C》2004,28(6):584-587
利用能量为164—180MeV的35Cl束流,通过149Sm(35Cl,p4n)反应研究了179Pt的高自旋态能级结构.进行了γ射线的激发函数、X γ和γγt符合测量,建立了基于12-[521],52-[512]和72+[633]组态的3个转动带.实验上观测到12-[521]带在hω=0.27MeV附近顺排角动量突然增大,且72+[633]带具有较大的旋称劈裂.通过比较奇APt同位素和179Pt的同中子素能级结构的系统性,对相关现象进行了分析和讨论. 相似文献
7.
8.
报道了利用兰州重离子研究装置提供的26Mg重离子束流轰击243Am靶产生和鉴别已知超重核素266Bh的实验结果。利用转轮收集探测装置依靠母子核遗传关系通过观测Bh同位素与其子核Db和Lr之间的α-α关联事件来鉴别266Bh。实验中观测到266Bh的α能量为(9.03 ± 0.08)MeV, 与日本理化学研究所在合成113号元素中第一个衰变链中观测到266Bh的α能量为9.07 MeV相近。 266Bh的半衰期为0.66+0.59-0.26 s, 从实验得到的Qα也符合Z=107的Qα随中子数变化的系统性。The isotope of 266Bh was produced and identified definitely in bombardments of 243Am target with 162 MeV 26Mg ions at HIRFL. Identification was made by observation of correlated α particle decays between the Bh isotopes and their Db and Lr daughters using a rotating wheel system. The measured α energy for 266Bh is (9.03±0.08) MeV, and this value close to the 9.07 MeV for 266Bh observed in the first chain of element 113 at RIKEN. The half life of 266Bh is 0.66+0.59 -0.26 s. The Qα value derived from this experiment fits well into the general trend in a “Qα N systematics” for the isotopes with Z = 107. 相似文献
9.
石峰 吕军光 卢红 王焕玉 马宇蒨 胡涛 周莉 蔡啸 孙丽君 俞伯祥 方建 谢宇广 安正华 王志刚 高旻 李新乔 徐岩冰 王平 孙希磊 章爱武 薛镇 刘宏邦 王晓东 赵小芸 郑阳恒 孟祥承 王辉 《中国物理 C》2011,35(1):50-55
Silicon photomultipliers (SiPMs) are a new generation of semiconductor-based photon counting devices with the merits of low weight, low power consumption and low voltage operation, promising to meet the needs of space particle physics experiments. In this paper, comparative studies of SiPMs and traditional vacuum photomultiplier tubes (PMTs) have been performed regarding the basic properties of dark currents, dark counts and excess noise factors. The intrinsic optical crosstalk effect of SiPMs was evaluated. 相似文献
10.
The low energy particle detector (LEPD) is one of the main payloads onboard the China seismic electromagnetic satellite (CSES). The detector is designed to ascertain space electrons (0.1-10 MeV) and protons (2-50 MeV). It has the capability of identifying the electrons and protons, to measure the energy spectrum and the incident angle of the particles. The LEPD is made up of a silicon tracker system, a CsI (Tl) mini-calorimeter, an anti-coincidence system made by plastic scintillator, as well as electronics and a data acquisition system (DAQ). The tracker is also a kind of E-E telescope; it consists of two layers of double-sided silicon strip detectors (DSSD). The signals emerging from the silicon tracker can be read out by two pieces of application specific integrated circuit (ASIC), which also can generate an event trigger for the LEPD. The functions of the DSSD system in the LEPD for charged particles were tested by 241Am @5.486 MeV α particles. The results show that the DSSD system works well, and has high performance to detect charged particles and measure the position of incident particles. 相似文献