中国工程物理研究院的核物理,核技术及相关学科的研究

本文概要地介绍中国工程物理研究的核物理、核技术及相关学科的研究与发展。内容包括九个方面：脉冲核反应体系的诊断学；中子学；高离化态原子物理学；激光惯性约束核聚变与高温高密度等离子体物理；Ｘ射线激光；加速器物理与技术；核电子学；核军备控制物理学及核技术应用等。     

21世纪：核物理与核技术应用的新时代

２１世纪：核物理与核技术应用的新时代从本世纪开始，核物理与核技术经历了极其深刻的革命，并在许多科学技术领域中引起深刻的变革，派生出了许多分支学科．此外，核物理与核技术和其他学科之间的渗透，又产生了许多交叉学科．可以说，２０世纪，核物理与核技术每时每刻...     

MCNP程序在核技术中的应用研究

叙述了MCNP,所程序在核临界计算、核保障技术和中子慢化实验装置模拟等方面的成功应用以及为此所做的进一步开发工作.对MCNP的进一步开发做了简要讨论.     

高技术与核能、核技术

 一、核能、核技术的基本内涵“高技术”一词起源于美国,目前尚没有统一的定义.多数人认为,高技术是指那些基本原理建立在最新科学成就基础上,并能创造较高的经济效益,具有较强增值作用,能向经济、社会各个领域广泛渗透的新技术.高技术一般可分为两大类.一类称为高准度技术.如航天技术、导弹技术以及我们这里将要介绍的核能与核技术;另一类称为高效益技术,如微电子、生物工程、新能源、激光、新材料等等.当然,两者之间并没有严格的界线.例如,核技术领域里的核应用技术就介于两者之间,它既有高准度技术的特征,又能产生高效益.     

基于HIAF的物理研究(英文)

在2010年,中国科学院近代物理研究所向国家发展和改革委员会建议了重大科技基础设施--强流重离子加速器装置（High Intensity Heavy-ion Accelerator Facility,简称HIAF）。经过一系列评估和论证,HIAF于2015年12月被国家发展改革委立项。HIAF建设地址位于广东省惠州市,计划于2018年年底正式开工建造。HIAF由超导直线加速器、同步增强器、高能放射性束流线、储存环谱仪以及若干实验测量装置构成,总投资约为25亿人民币。依托HIAF,我们将拓展核素存在版图,研发先进实验技术和方法,开展前沿物理研究;同时,开展重离子束应用研究,服务国家经济社会发展。简要介绍拟建的加速器系统、实验测量装置以及相关的物理研究计划。The Institute of Modern Physics, Chinese Academy of Sciences, proposed the Major National Science and Technology Infrastructure Facility named as High Intensity Heavy-ion Accelerator Facility (HIAF) in 2010. After a series of assessments charged by the National Development and Reform Commission of China, HIAF was officially approved by China government in December, 2015. HIAF will be constructed in Huizhou, Guangdong Province, and the groundbreaking ceremony of construction is scheduled around the end in the year of 2018. HIAF is composed of a superconducting Linac, a booster ring, a high-energy radioactive beam line, a storage ring, and a number of experiment setups. The total investment of HIAF is about 2.5 billion Chinese Yuan. The major goals for HIAF are to explore the hitherto unknown territories in nuclear chart, to approach the experimental limits, to open new domains of physics researches in experiments, and to develop new ideas and heavy-ion applications beneficial to the societies. In this paper, the accelerator complex of HIAF is briefly introduced, and the experimental setups and associated physics research program are presented.     

核物理与核探测、核分析技术的应用

文章概要介绍了随着核物理研究发展起来的辐射和粒子探测的原理、方法和主要技术,举例介绍了相关核物理与核探测、核分析的典型技术及其在高精度测量和医学中的广泛应用,如活化分析技术、穆斯堡尔谱学、核磁共振技术、加速器质谱技术、核医学成像、同步辐射技术、中子散射分析、放射性示踪技术等等.     

核物理与核探测、核分析技术的应用

文章概要介绍了随着核物理研究发展起来的辐射和粒子探测的原理、方法和主要技术,举例介绍了相关核物理与核探测、核分析的典型技术及其在高精度测量和医学中的广泛应用,如活化分析技术、穆斯堡尔谱学、核磁共振技术、加速器质谱技术、核医学成像、同步辐射技术、中子散射分析、放射性示踪技术等等.     

核物理与等离子体物理学科研究进展

1 理论物理 1．1 等离子体物理 深入开展了激光等离子体相互作用理论研究。为了模拟和研究激光与大尺度黑腔等离子体相互作用问题，分析了激光入射场、散射波场和离子声波的传播的耦合关系，考虑动力学效应，提出了描述自聚焦、受激散射非线性演化的耦合模型，完成流体程序的物理方案；研究了SRS时空演化机制，发现一些新物理现象；对超强激光与超高密度等离子体作用问题进行模拟，研究了高能电子、单能离子产生的新特征。     

Evolution of nuclear spectroscopy at Saha Institute of Nuclear Physics

Experimental studies of nuclear excitations have been an important subject from the earliest days when the institute was established. The construction of 4 MeV proton cyclotron was mainly aimed to achieve this goal. Early experiments in nuclear spectroscopy were done with radioactive nuclei with the help of beta and gamma ray spectrometers. Small NaI(Tl) detectors were used for gamma-gamma coincidence, angular correlation and life time measurements. The excited states nuclear magnetic moments were measured in perturbed gamma-gamma angular correlation experiments. A high transmission magnetic beta ray spectrometer was used to measure internal conversion coefficients and beta-gamma coincidence studies. A large number of significant contributions were made during 1950–59 using these facilities. Proton beam in the cyclotron was made available in the late 1950’s and together with 14 MeV neutrons obtained from a C-W generator a large number of short-lived nuclei were investigated during 1960’s and 1970’s. The introduction of high resolution Ge gamma detectors and the improved electronics helped to extend the spectroscopic work which include on-line (p ₇ p′γ) and (p ₇ nγ) reaction studies. Nuclear spectroscopic studies entered a new phase in the 1980’s with the availability of 40–80 MeV alpha beam from the variable energy cyclotron at VECC, Calcutta. A number of experimental groups were formed in the institute to study nuclear level schemes with (α ₇ xnγ) reactions. Initially only two unsuppressed Ge detectors were used for coincidence studies. Later in 1989 five Ge detectors with a large six segmented NaI(Tl) multiplicitysum detector system were successfully used to select various channels in (α ₇ xnγ) reactions. From 1990 to date a variety of medium energy heavy ions were made available from the BARC-TIFR Pelletron and the Nuclear Science Centre Pelletron. The state of the art gamma detector arrays in these centres enabled the Saha Institute groups to undertake more sophisticated experiments. Front line nuclear spectroscopy works are now being done and new informations are obtained for a large number of nuclei over a wide mass range. Currently Saha Institute is building a multi-element gamma heavy ion neutron array detector (MEGHNAD), which will have six high efficiency clover Ge detector together with charged particle ball and other accessories. The system is expected to be usable in 2002 and will be used in experiments using high energy heavy ions from VECC.     

Strangeness Nuclear Physics at J-PARC

After the big earthquake in the east part of Japan on March 11, 2011, the beams in the hadron experimental hall at J-PARC have been successfully recovered in February, 2012. The experimental program using pion beams is now on-going with the primary proton beam power of ~5 kW. Before a long summer shutdown scheduled in 2013, several experiments in strangeness nuclear physics are going to take data. In this period, we anticipate the beam power would exceed 10 kW and the experiments to use K ^? beams will start. The experimental program is explained briefly.     

Nuclear Few-Body Physics at FAIR

The FAIR facility, to be constructed at the GSI site in Darmstadt, will be addressing a wealth of outstanding questions within the realm of subatomic, atomic and plasma physics through a combination of novel accelerators, storage rings and innovative experimental set-ups. One of the key installations is the fragment separator Super-FRS that will be able to deliver an unprecedented range of radioactive ion beams (RIBs) in the energy range of 0?C1.5?GeV/u to the envisaged experiments collected within the NuSTAR collaboration. This will in particular permit new experimental investigations of nuclear few-body systems at extreme isospins, also reaching beyond the drip-lines, using the NuSTAR-R³B set-up. The outcome of pilot experiments on unbound systems are reported, as well as crucial detector upgrades.     

实验核物理进展

本文回顾我所实验核物理科研人员在低能核反应机制、中子物理、核衰变性质及核结构研究中所做一系列工作,同时简单介绍了目前工作和设想． The paper reviews the research activities at SINR on experimental nuclear physics. The studies have been focused on mechanism of nuclear reactions, neutron physics,properties of nuclear decay and nuclear structure. Brief introductions are given to the ongoing research projects and future plans in the field of research.     

南开大学奇异性核物理的理论研究

简要介绍了南开大学核物理组在奇异性核物理方面的理论研究工作. 已经完成的工作有核介质内超子平均自由程的理论计算, 奇异性核物理方面已完成的其他4个理论研究课题是, 不同重子杂质对原子核的影响、重味重子超核、核物质内的eta-介子以及K介子原子核的性质.     

中物院远红外自由电子激光实验研究

中国工程物理研究院基于射频直线加速器技术的远红外自由电子激光(FIR-FEL)实验取得阶段性进展,于2005年3月24晚8时30分首次出光, 并多次重复. 中心波长115μm, 谱宽1%.介绍了实验系统的主要组成部分和主要实验结果.     

X-ray fluorescence activities at Saha Institute of Nuclear Physics,India

This paper covers different aspects related to X-ray fluorescence activities at Saha Institute of Nuclear Physics, Kolkata, India. In its first part, experiments on basic physical problems are illustrated and in the second part, some applications related to X-ray fluorescence are discussed.     

兰州CSR与高密核物理

讨论在兰州 Ｃ Ｓ Ｒ 上产生高密核物质的可能性以及在末态出现的相应信号． 估计了 Ｃ Ｓ Ｒ 所能达到的核物质密度, 分析了由于手征对称性部分恢复引起的强子阈下产生和强子流在 Ｃ Ｓ Ｒ 能区的特征． The possibility to produce highly dense nuclear matter at CSR of Lanzhou and the corresponding signals at final state are discussed. Especially, the maximum baryon density reached at CSR is estimated, and the subthreshold production and hadronic flow risen from the partial restoration of chiral symmetry at CSR energies are analyzed.     

Applied nuclear physics at Yerevan Physics Institute

A number of areas of development of applied studies at the Yerevan Physics Institute (YerPhI) are viewed. The main area is research into possibilities to produce radio nuclides for nuclear medicine on the linear accelerator of electrons at YerPhI. We consider also the methods for employment of neutron beams obtained from photonuclear reactions for boron-capture neutron therapy and for nondestructive detection of fission materials.     

利用SLEGS开展夸克和胶子层次上的核物理研究

通过对国际上中能核物理的发展,特别是前沿领域中的现状的回顾,阐述了利用在上海原子核所计划建造的第三代同步辐射加速器(SSRF)上建立新一代的激光 电子康普顿背散射γ射线源(SLEGS)从事夸克和胶子层次上的中能核物理研究的科学目标及研究内容. The proposed SLEGS (Shanghai Laser Electron backscattering Gamma Source) will be a circular and linear polarization, new generation, high quality γ ray source with Eγ=0.2-0.87 GeV. The major scientific focus of nuclear physics research at SLEGS will be investigations of the microscopic quark gluon aspects of nucleons , nucleon resonance states and nuclei to test and develop non perturbative QCD. Using polarized photon induced reactions on unpolarized and polarized nucleon target such as γN→γ N, ...