核素等时性质量测量实验中一种基于离子速度纯化次级束的方法

等时性质量谱仪（Isochronous Mass Spectrometry,IMS）是测量短寿命核素质量的有效实验装置。在IMS核素质量测量实验过程中,目标核素通过弹核碎裂反应产生,并被次级束流线分离、传输后注入到储存环内。由于远离稳定线的目标核素产额非常低,经常伴随大量杂质核素产生,这些杂质离子会加重飞行时间探测器（Time of Flight,TOF）系统的工作负担。在HIRFL-CSR利用IMS进行核素质量测量实验过程中,发展了一种进一步纯化筛选次级离子的方法,以减轻TOF系统的工作负担。基于次级离子在束流线中飞行速度的差异性,利用HIRFL-CSR踢轨磁铁（Kicker）系统,调节次级束流注入CSRe的时间,使次级离子得到进一步筛选和纯化后注入到CSRe内。在实验中,我们测试并验证了该方法的可行性,并讨论了它在纯化次级束流方面的作用。The isochronous Mass Spectrometry (IMS) is a powerful experimental instrument for measuring masses of short-lived nuclides.In the IMS,the nuclides of interest are produced via the projectile fragmentation reaction,then injected into the storage ring after the in-flight separation with beam line.The yields of the nuclides of interest are usually very small accompanying a huge amount of contaminant nuclides,aggravating the load of time-of-flight (TOF) detector.In the IMS nuclear mass measurement experiment conducted at the HIRFL-CSR,we developed a method of purifying the secondary beam fragments to ease the burden of the TOF detector,which is based on the differences of the ions' velocities in the beam line and realized by adjusting the injection time of secondary fragments using the Kicker system of the HIRFL-CSR.We tested and verified the method in an online experiment,and its performance is discussed in this paper.     

HIRFL-CSR六极磁铁数字电源研究与设计

设计了一台用于兰州重离子加速器HIRFL-CSR的六极磁铁数字电源, 该电源以H桥变换器为主拓扑结构电路, 采用Cyclone II FPGA作为核心硬件, 以Verilog语言实现了全数字化的PI调节算法。 电源输出电流达到了340 A, 直流电流稳定度达到了3.14×10-5, 达到了1×10-4的设计指标。One digital power supply was designed for the sextupole magnets of Cooler Storage Ring of the Heavy Ion Research Facility in Lanzhou (HIRFL CSR). It adopts H Bridge convertor as the main topology circuit and Cyclone II FPGA as the main hardware, and has realized fully digitized PI regulation arithmetic by Verilog language. The peak current of the power supply reaches 340 A and the stability approaches 3.14×10-5. Finally the power supply has achieved the designed specification of 1×10-4.     

电子冷却

本文概述电子冷却原理及其国际现状.This paper briefly describes the principle of electron cooling and the current status.     

兰州重离子加速器冷却储存环束流累积研究

对兰州重离子加速器冷却储存环加速器主体的主要功能环——主环的束流累积方法和设计进行了研究 .为了使主环对不同种类的重离子束流都具有较强的累积能力 ,在设计时考虑采用电子冷却参与下的两种束流累积方法 :多次多圈注入和射频堆积 .对这两种方法 ,电子冷却的冷却时间都是将束流累积到高流强的关键因素. The beam accumulation methods of HIRFL CSR(Heavy Ion Research Facility of Lanzhou and Cooler Storage Rings) project were studied. Two accumulation methods will be adopted to increase the beam intensity of CSRm. For both multiple multi turn injection method and RF stacking method, electron cooling of beam plays an important role.     

兰州重离子冷却储存环工程

兰州重离子加速器冷却储存环是兰州重离子研究装置的后续工程 .它的建造目的是将重离子束的能量提高到 1 Ge V/u附近 ,同时利用储存环电子冷却技术将束流品质提高一个数量级 ,并提供更多种类的重离子束 ,以开展更广范围和更高精度的物理实验 .兰州重离子加速器冷却储存环是一个双储存环系统 ,由一个主环和一个实验环构成 .对其总体布局、总体参数、主要功能进行了介绍. HIRFL- CSR, a new accelerator project at the Heavy Ion Research Facility in Lanzhou (HIRFL), is a multipurpose Cooling Storage Ring system which consists of a main ring (CSRm) and an experimental ring (CSRe). Beams from HIRFL will be accumulated and accelerated in CSRm, and then transported to CSRe for internal target experiments. The layout, major parameters and main functions of the CSR were described.     

HIRFL-CSR电子冷却系统

建议中的兰州重离子加速器冷却贮存环（ＨＩＲＦＬ－ＣＳＲ）拟采用电子冷却方法将重离子束冷却到３００ＭｅＶ／ｕ．最高电子能量为１６５ｋｅＶ,最大电子电流密度为０．２４４Ａ／ｃｍ２．叙述了ＣＳＲ电子冷却装置的初步方案． Electron cooling technique will be applied to the proposed Lanzhou heavy ion cooler-storage ring(HIRFL-CSR).A electron cooling device with a max-imum electron energy of 165keV and maximum current density of 0.244A/cm2 is planned to cool heavy ions up to energies of 300MeV/u.The prelimnary design for the cooling system is presented.