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.     

核固体物理学

核固体物理的研究给核物理学家为解决物理学基本问题作出新贡献提供了许多的良机．本文概要叙述理论研究背景及用核方法研究凝聚态物质微结构的一些新结果,报道用核方法研究材料组份,讨论辐照条件下固体的结构和行为． The study of nuclear solid-state physics provides many new opportunities for nuclear physicists to contribute to the solution of some of the most of the fundamental questions in physics. This paper gives a brief survey of theoretical background and some new results on the microstructure of condensed matter obtained by nuclear methods.The elemental composition of the materials with nuclear methods are presented. The structure and behaviour of the solids under irradiation is discussed.     

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。     

300＃反应堆及其在核技术中的应用

３００~＃反应堆是一座池式研究用反应堆．本文介绍该堆的基本特性、堆上的一些实验装置及其性能;综述了在该堆上所做的中子物理、核物理、核化学和材料科学等方面的工作,以及某些中子辐照产品及其应用的概况． reactor is a pool type of research reactor. In this paper the basic featureof the reactor, and several experimental devices and their properties are introduced. It wassummarized that the experiment and study work is developed on the reactor, such as neutronand nuclear physics, nuclear chemistry, material science, and a few irradiated products byneutron and their applications and so on.     

核核碰撞的最新进展——第四届核核碰撞国际会议简介

本文介绍了第四次核核碰撞国际会议的主要报告内容,包括核结构、核反应机制、超相对论重离子碰撞、放射性核束及其核物理研究、核天体物理学及核技术应用.同时,也介绍了各个领域已经取得的最新进展及今后研究的热门课题. In this paper the main reports given on Nucleus—Nucleus Collisions International Con-ference Ⅳ are briefly introduced.It includes nuclear stracture,nuclear reaction mechanism,super rela-tivistic HIC,redioactive nuclear beams and its nuclear physics research,nuclear astrophysics and appli-cations of nuclear technigue.The Latest developments in every fields and the top research point in thenear future are introduced.     

中国医学物理学的过去、现在与未来

医学物理（medical physics，MP）是把物理学的原理和方法应用于人类疾病的预防、诊断、治疗和保健的一门交叉学科，是物理学与医学实践相结合的一门独立的分支学科．它是研究人类疾病诊、治过程中的物理现象，并用物理方法表达这种现象．医学物理包括放射肿瘤物理（rsdiation oncdogy physics，ROP）、医学影像物理（medical imaong physics，MIP）、核医学物理（nuclear medicine physics，NMP），其他非电离辐射如核磁、超声、微波、射频、激光等物理因子在医学中的应用，和保健物理（heath physics，HP）等分支内容．医学物理学和生物医学工程学（biomedical engineefing，BME）是一对栾生的兄弟学科，分别从物理学的角度（前者）和工程学的角度（后者）研究人类疾病诊断、治疗及健康保健过程中的生命现象和采取相应的物理措施和工程手段。医学物理学与物理医学（physical medicine，PM）是完全两个不同的概念，前者是物理学的分支，后者是医学的分支．自上世纪60年代以来，中国医学物理学有了很大的进展，推动了中国现代放射肿瘤学、核医学和医学影像学的发展；成立了自己的学术组织，并成为国际医学物理组织（IOMP）的成员国组织．随着中国逐步奔入小康社会，为适应人民大众对健康的需求和现代化医院发展的需要，中国医学物理应该加快发展．     

我国核天体物理前沿研究进展

核天体物理是研究微观世界的核物理与研究宏观世界的天体物理融合形成的交叉学科,其主要研究目标是:宇宙中各种化学元素核合成的过程、时间、物理环境、天体场所及丰度分布;核反应（包括带电粒子、中子、光子及中微子引起的反应、β衰变及电子俘获）如何控制恒星的演化过程和结局。近十多年来获得的大量实验和理论研究使核天体物理研究进入了一个蓬勃发展的新阶段。文章总结了以兰州重离子加速器、北京串列加速器和国家天文台为基础,结合国际合作,在核天体物理研究领域对直接测量、间接测量、衰变测量、质量测量、理论计算、网络计算、天文观测等关键科学问题进行的研究进展。也展望了核天体物理的关键科学问题,这些关键问题包括:（1）在地面实验室、尤其是地下实验室开展天体物理能区重要热核反应截面的直接测量;（2）高能区带电粒子反应截面向天体物理能区的合理外推;（3）恒星平稳核燃烧阶段和爆发性天体事件中关键核反应截面的间接测量;（4）爆发性天体事件中所涉及的大量远离稳定线核素的质量、衰变特性和共振态性质的研究;（5）建立并不断完善核天体物理数据库,发展网络模拟程序,系统研究元素核合成的天体场所、丰度分布;（6）宇宙中铁以上元素的来源之谜。Nuclear astrophysics is an interdisciplinary research field. It composes of nuclear physics, which studies micro phenomena, and astrophysics which studies macroscopic phenomena in our world. The main research goals of nuclear astrophysics are:(1) how, when and where chemical elements are synthesized and what is their final abundance distribution in the universe; (2) how nuclear processes (reactions induced by charged particles, neutrons, photons and neutrinos, beta decays and electron capture processes) determine the evolution and the ultimate fate of stars. At present, nuclear astrophysics has been developed into a new prosperous stage with a huge number of experimental and theoretical progresses. This paper summarized the current progress of nuclear astrophysics in China, in the subfiels of direct and indirect measurement of key reactions, measurement of mass and decay, as well as the theoretical calculation and network simulation. In present paper, the prospects to solve the key scientific nuclear astrophysics problems are represented. These key problems include (1) direct measurement of important reactions at astrophysical energies in the laboratory on the earth surface and in the underground laboratory; (2)extrapolation of cross sections at higher energies for the reactions induced by charged particles; (3) indirect measurement of key reactions in the hydrostatic and explosive nuclear processes; (4) study of the mass, the properties of decay and resonant states for the nuclides far from the stability line in explosive astrophysical events; (5) establish and improve the database for nuclear astrophysics, and develop network simulation codes, and systematically study astrophysical sites and abundance distribution of nucleosynthesis; (6) origin of the elements heavier than iron in the universe.     

极化电子源的原理及实验研究

简单介绍了极化电子束的获得,即极化电子源,讨论了对电子束极化度的测量,极化电子与原子散射,以及极化电子束在固物理、生物物理、核物理与粒子物理中的应用． The getting of polarized electrons was briefly introduced, that is the source of polarized electrons. The measurement of polarization in future, the application of polarized electrons in atomic and molecular physics, condensed physics, biological physics, nuclear and particle physics were discussed.     

核物理研究新进展

本文介绍了国际核物理研究的趋势,核物理研究的前沿已从传统核物理转向亚核自由度变得重要的领域,讨论了在核结构、核反应、相对论性重离子碰撞、亚核自由度、放射性核束和核天体物理学等领域所获得的最新成果. It is presented the trend of the nuclear physics research in the world,the fron- tier of nuclear physics research has been moved from the traditional nuclear physics to the field in which the subnuclear freedoms become very important.New research results obtained in the fields of nuclear structures,nuclear reactions,relativistic heavy ion collisions, subnuclear freedoms,radioactive nuclear beams and nuclear astrophysics are discussed.     

基于不稳定核基本性质测量的原子核结构研究

精密激光谱学是通过测量核素原子光谱的超精细结构和同位素移位来研究原子核的基本性质,为原子核自旋、磁矩、电四极矩及电荷均方根半径的确定提供了一种模型独立的测量方式。这些原子核基本性质的测量,能够比较精确地描述原子核微观结构的演化。近年来,随着放射性束流装置的发展,产生远离β-稳定线的丰中子/丰质子核素成为可能,也进一步促进了高分辨和高灵敏度的激光谱技术更加广泛的应用。简单介绍了基于放射性核素超精细结构的激光谱学测量原理,并通过几个经典实例来回顾近年来激光谱学在原子核奇特结构研究领域的独特贡献。主要通过分析几个重要核区原子核的基本性质,结合大尺度壳模型、ab initio理论、密度泛函理论等,来探索丰中子核中展现出来的一些新的奇特现象,如晕结构、幻数演化、形状共存等。High-precision laser spectroscopy technique is used to determine the ground state properties of exotic nuclei by probing its electronic hyperfine structure and isotope shift. It provides a model-independent measurement of nuclear spin, magnetic moment, electric quadrupole moment and charge radii. These nuclear parameters can be used to investigate the nuclear structure evolution and the nuclear shapes. With the development of accelerators and isotope separators, exotic isotopes far from β stability became accessible experimentally, which enhanced the capability of the laser spectroscopy technique being applied in the field of nuclear physics. A brief introduction to experimental principle is given, followed by a review of several typical examples for the experimental investigations in the different regions of nuclear chart. This aims to demonstrate the contributions of ground state properties measurement by using laser spectroscopy technique to the nuclear structure study of exotic isotopes. This discussion involves several different nuclear theory models in order to interpret the exotic phenomena observed in the neutron-rich isotopes, such as halo structure, shell evolution, shape coexistence and so on.     

High-energy,nuclear, and QED processes in strong laser fields

Various applications of ultraintense laser fields in particle physics, nuclear science, and quantum electrodynamics are presented. We discuss laser-driven lepton-pair creation, photon splitting, high-harmonic generation from both vacuum and muonic atoms, and direct nuclear excitation. All of these processes may come into experimental reach by near-future laser technology.     

上海激光康普顿散射伽马源的发展和展望

激光康普顿散射(Laser Campton Scattering, LCS)光源,是一种基于相对论电子束与激光光子相互作用的新型X-ray或Gamma-ray光源。它具有能量高、波长短、脉冲快和峰值亮度高的特性,已成为国际先进光源技术的重要选项之一。本文介绍了激光康普顿散射光源的产生原理、国内外发展现状以及目前国际上运行和在建的激光康普顿散射光源装置,其中重点介绍了上海光源二期正在建设的上海激光电子伽马源(Shanghai Laser Electron Gamma Source, SLEGS)装置,以及在这一光源装置上可以开展的核物理、核天体物理、核废料处理及核医学应用等研究。随着上海软X射线自由电子激光试验装置(Soft X-ray Free Electron Laser, SXFEL)升级为用户装置,以及未来十三五国家重大科技基础设施-硬X射线自由电子装置(Shanghai HIgh repetition rate XFEL aNd Extreme light facility,SHINE)的建设完成,基于直线电子加速器(LINear ACcelator, LINAC)的康普顿散射光源的伽马能量将会达到GeV量级的高能量。超短脉冲、高极化度、高通量的激光康普顿散射光源将迎来新的发展机遇,基于康普顿伽马光源的核物理、天体物理、粒子物理及应用基础研究也必将迈上一个新台阶。     

Laser applications in nuclear physics: Present and future

The use of lasers for nuclear physics research is widespread and growing rapidly. The major impact in nuclear structure research has come from nuclear size and shape determinations for nuclei far from stability via high resolution isotope shift measurements. In addition, systematic data on nuclear magnetic and quadrupole moments have been obtained via the hyperfine splitting resolved in laser fluorescence studies of atomic spectra in both stable and unstable systems. The tunability, high intensity and inherent polarization of laser light can be used to polarize atomic nuclei for nuclear reaction studies. The rapid efficient polarization of unstable nuclei with lasers also presents opportunities for new research in nuclear physics. In this paper the physics of the laser interaction for the studies indicated will be introduced. Some examples of work completed and in progress will be presented primarily from on-line laser studies at charged particle accelerators. Extensions of current research, particularly with respect to possible studies of short-lived nuclei, are discussed and the synergistic effects of certain advances in quantum electronics and nuclear physics described.     

浅谈现代物理学与工程技术--献给2005世界物理年

在现代社会进步的历程中，基础性很强的物理科学和应用性很强的工程技术，扮演着不同的角色．但它们之间却存在着紧密的相互联系和深刻的相互作用．文章首先以物理学与核能、激光、航天三个领域的关系为例，说明现代物理学对许多工程技术领域的开创起着先导和引领的作用，而工程技术不仅直接地创造生产力，而且反过来开拓并深化了物理学研究的疆域，为之提供了更加丰富、精致的环境条件和更有力的研究手段．进一步阐明现代物理学与工程技术的这种关系具有普遍性和发展性．物理学与工程技术不仅互相促进、携手并进、相互渗透，而且与哲学、社会科学密切相关，共同推动着经济与社会的发展，从生产方式、生活方式和思想观念上深刻地改变着人类文明的进程．物理学与工程技术在认识世界和改造世界中所担负的责任，要求物理学家和工程技术专家应该具备一些共同的优良品格：高度的社会责任感和为科技事业献身的精神，唯真求实、开拓创新以及科学的思维方法与哲学造诣等．     

回旋加速器的应用

回旋加速器在核物理研究中发挥过重要的作用,现在和将来仍然是核物理研究领域的主要工具之一,随着核科学,核技术及核医学等高新技术的发展,回旋加速器在这些领域中的应用空间和发展前景已引起人们的关注,文章介绍了回旋加速器发展概况及其在核物理,核医学与核技术等领域的主要应用。     

Laser Driven Fusion

Laser-driven fusion, although requiring the use of an unusual source of pulsed energy, depends in its main features on well known and verified results of hydrodynamics and nuclear physics. Under optimized conditions these allow energy breakeven by the fusion process to occur under conditions which appear to be well within the range of present technology. Achieving the energy multiplication required for practical application is expected to be more difficult but not infeasible within short-range projections of the development of laser technology. The feasibility of laser-driven fusion power plants appears to rest more on pellet and laser ecomonics than on reactor technology. The study of these problems is underway and will certainly be greatly intensified as the prediction of the basic processes is experimentally confirmed.     

近代物理学与核技术

核技术是本世纪最尖端技术之一．它是以１９世纪末和２０世纪发展起来的现代物理学为基础的．核技术发展如此之快，没有现代物理学的支持是不可能的．文章讨论了核技术对经济、科学、技术的影响，着重强调现代物理学的发展直接影响核技术的发展     

Nuclear Physics with 10 PW laser beams at Extreme Light Infrastructure – Nuclear Physics (ELI-NP)

The field of the uncharted territory of high-intensity laser interaction with matter is confronted with new exotic phenomena and, consequently, opens new research perspectives. The intense laser beams interacting with a gas or solid target generate beams of electrons, protons and ions. These beams can induce nuclear reactions. Electrons also generate ions high-energy photons via bremsstrahlung processes which can also induce nuclear reactions. In this context a new research domain began to form in the last decade or so, namely nuclear physics with high power lasers. The observation of high brilliance proton beams of tens of MeV energy from solid targets has stimulated an intense research activity. The laser-driven particle beams have to compete with conventional nuclear accelerator-generated beams. The ultimate goal is aiming at applications of the laser produced beams in research, technology and medicine. The mechanism responsible for ion acceleration are currently subject of intensive research in many laboratories in the world. The existing results, experimental and theoretical, and their perspectives are reviewed in this article in the context of IZEST and the scientific program of ELI-NP.     

Particle accelerator physics and technology for high energy density physics research

Interaction phenomena of intense ion- and laser radiation with matter have a large range of application in different fields of science, extending from basic research of plasma properties to applications in energy science, especially in inertial fusion. The heavy ion synchrotron at GSI now routinely delivers intense uranium beams that deposit about 1 kJ/g of specific energy in solid matter, e.g. solid lead. Our simulations show that the new accelerator complex FAIR (Facility for Antiproton and Ion Research) at GSI as well as beams from the CERN large hadron collider (LHC) will vastly extend the accessible parameter range for high energy density states. A natural example of hot dense plasma is provided by our neighbouring star the sun, and allows a deep insight into the physics of fusion, the properties of matter at high energy density, and is moreover an excellent laboratory for astroparticle physics. As such the sun's interior plasma can even be used to probe the existence of novel particles and dark matter candidates. We present an overview on recent results and developments of dense plasma physics addressed with heavy ion and laser beams combined with accelerator- and nuclear physics technology.     

基于激光等离子体的X/γ辐射研究进展

随着激光技术的不断发展,激光功率突破10 PW量级,激光与物质相互作用进入近量子电动力学（QED）范畴。从弱相对论激光到相对论激光再到强相对论激光,激光场与物质的耦合可以产生能量从keV到MeV甚至GeV的X/γ射线。这些辐射具有通量大、亮度高、能量高和脉宽短等特点,在核物理、高能量密度物理、天体物理等基础研究以及材料科学、成像、医学等领域具有广泛应用前景。系统梳理了近年来相对论强激光与气体、近临界密度等离子体及固体靶相互作用,通过诸如同步辐射、betatron和类betatron辐射、Thomson散射和非线性Compton散射过程等产生高能X/γ射线的最新研究进展,总结了各种方案产生的X/γ射线的品质因子和潜在应用,并为下一步基于强激光大科学装置的实验研究提供理论参考。