河南理工大学材料科学与工程学院, 焦作 454000
由创伤、肿瘤和感染等原因引起的骨缺损通常面积较大, 超过了骨自愈范围而不能自修复。因此, 需要使用骨水泥对面积较大的骨缺损部位进行填充修复。磷酸钙水泥(calcium phosphate cement, CPC)是目前临床常用的一种骨水泥, 可任意塑形, 具有良好生物活性和生物相容性, 近几十年来得到国内外学者的广泛研究。然而, 从临床实践经验来看, CPC的应用范围有限, 仍需要对其进行性能改进。本文主要分为两部分: 在理化性能部分总结了CPC在力学强度、可注射性、抗溃散性和放射不透明性等四方面的改性方法; 在生物学性能方面讨论了CPC成骨活性、生物可降解性和载药性方面的改性研究。
磷酸钙水泥 力学强度 可注射性 抗溃散性 放射不透明性 成骨活性 生物可降解性 载药性 calcium phosphate cement mechanical strength injectability anti-collapsibility radiation opacity osteogenic activity biodegradability drug loading property
Author Affiliations
Abstract
1 School of Engineering, Osaka University, Suita, Osaka 565-0871, Japan
2 Institute of Laser Engineering, Osaka University, Suita, Osaka 565-0871, Japan
3 Institute of Radiation Physics, Helmholtz Zentrum Dresden Rossendorf, 01328Dresden, Germany
Thanks to a rapid progress of high-power lasers since the birth of laser by T. H. Maiman in 1960, intense lasers have been developed mainly for studying the scientific feasibility of laser fusion. Inertial confinement fusion with an intense laser has attracted attention as a new future energy source after two oil crises in the 1970s and 1980s. From the beginning, the most challenging physics is known to be the hydrodynamic instability to realize the spherical implosion to achieve more than 1000 times the solid density. Many studies have been performed theoretically and experimentally on the hydrodynamic instability and resultant turbulent mixing of compressible fluids. During such activities in the laboratory, the explosion of supernova SN1987A was observed in the sky on 23 February 1987. The X-ray satellites have revealed that the hydrodynamic instability is a key issue to understand the physics of supernova explosion. After collaboration between laser plasma researchers and astrophysicists, the laboratory astrophysics with intense lasers was proposed and promoted around the end of the 1990s. The original subject was mainly related to hydrodynamic instabilities. However, after two decades of laboratory astrophysics research, we can now find a diversity of research topics. It has been demonstrated theoretically and experimentally that a variety of nonlinear physics of collisionless plasmas can be studied in laser ablation plasmas in the last decade. In the present paper, we shed light on the recent 10 topics studied intensively in laboratory experiments. A brief review is given by citing recent papers. Then, modeling cosmic-ray acceleration with lasers is reviewed in a following session as a special topic to be the future main topic in laboratory astrophysics research.
collisionless shock compressible hydrodynamics cosmic rays equation of state high-energy-density plasmas intense laser magnetic turbulence opacity experiment particle accelerations relativistic plasmas turbulent mixing wakefield acceleration Weibel instability High Power Laser Science and Engineering
2021, 9(4): 04000e49
强激光与粒子束
2020, 32(9): 092003
Author Affiliations
Abstract
1 Institute of Applied Physics and Computational Mathematics, Beijing 10094, China
2 Laboratory of Computational Physics, Beijing 100088, China
3 National Hi-Tech Inertial Confinement Fusion Committee of China, Beijing 100088, China
A sharp density increase (referred to as density incrustation) of the Au plasmas in the radiative cooling process of high-Z Au plasmas confined by low-Z CH plasmas is found through the radiative hydrodynamic simulations. The temperature of Au plasmas changes obviously in the cooling layer while the pressure remains constant. Consequently, the Au plasmas in the cooling layer are compressed, and the density incrustation is formed. It is also shown that when the high-Z plasma opacity decreases or the low-Z plasma opacity increases, the peak density of the density incrustation becomes lower and the thickness of the density incrustation becomes wider. This phenomenon is crucial to the RayleigheTaylor instability at the interface of high-Z and low-Z plasmas, since the density variation of Au plasmas has a considerable influence on the Atwood number of the interface.
Density incrustation Density incrustation Radiation hydrodynamics Radiation hydrodynamics Opacity Opacity Matter and Radiation at Extremes
2016, 1(5): 249
北京应用物理与计算数学研究所, 北京 100094
不同辐射建模对于腔内辐射场描述的精确程度不同,需要分析不同建模对腔内辐射温度的影响。开展了三温建模与辐射多群输运建模下LARED集成程序数值模拟两孔球型黑腔模型,实现了球腔的完整数值模拟。数值模拟结果表明,三温与辐射多群输运模拟的等离子体状态接近,辐射温度存在差异。物理分析显示辐射温度差异的主要原因是使用的辐射不透明度,修改辐射不透明度参数后的三温计算结果与输运计算符合更好,从而可以用三温建模更快更准确地估计出所需的激光能量和功率。
惯性约束聚变 辐射多群输运 二维LARED集成程序 辐射热传导 辐射不透明度 inertial confinement fusion multi-group radiation transfer 2D LARED-Integration code radiation thermal conduction opacity 强激光与粒子束
2016, 28(4): 042001
中国工程物理研究院 激光聚变研究中心, 四川 绵阳 621900
利用空间分划的平衡辐射输运方程, 结合Multi1D辐射流体程序计算了辐射驱动内爆芯部的X光发射空间分布, 计算结果表明:高能X光的发射区域随X光子能量的增大而减小, 低能X光的发射区域随X光子能量的减小而减小。考虑芯部中间区域和芯部边缘区域物质的不透明度, 利用遗传算法计算了芯部的温度空间分布, 并与模拟结果作了比较, 二者的不确定度小于4%。
内爆芯部 空间分划辐射输运方程 遗传算法 不透明度 implosion core zone spatial radiation transport equation genetic algorithm opacity
1 西南民族大学物理系,成都,610041
2 四川大学原子分子物理所,成都,610065
用屏蔽氢离子模型计算了冲击压缩产生的温度T~1.8 eV,密度ρ~0.0044 g/cm3稠密氩等离子体随光子能量变化的辐射不透明度,并与实验作了比较,探讨了冲击压缩产生的稠密等离子体中自由-自由吸收、束缚-自由吸收和束缚-束缚吸收对不透明度的贡献.计算结果表明,对冲击压缩产生的稠密等离子体,自由-自由吸收对不透明度的贡献非常大,特别当光子能量较低时(hv~2.0 eV )自由-自由吸收为不透明的主要部分,因此较好地计算自由-自由吸收项对冲击压缩产生的稠密等离子体不透明度的研究是非常重要的.
冲击压缩 稠密氩等离子体 不透明度 Shock-generated plasmas Argon Opacity 原子与分子物理学报
2005, 22(3): 578
中国工程物理研究院流体物理研究所冲击波物理与爆轰物理实验室,四川,绵阳919信箱102分箱,621900
用二级氢气炮作为冲击压缩加载工具和多通道瞬态辐射高温计作为主要测量系统,测量了冲击压缩氦气等离子体的光辐亮度历史(初始温度293 K,初始压力为0.6 MPa和1.2 MPa两种).根据实测记录信号波形的有关特征量,计算得到了氦等离子体的光谱吸收系数κ(λ)和冲击压缩铝基板表面的光反射率R.结果发现:受冲击铝基板表面的光反射率~0.4(比其初始反射率0.8约降低一半),与Erskine的数据相同;对于光谱吸收系数的实测数据,本文目前未能给出合理的物理解释.
冲击温度 辐射不透明度 Shock Temperatures Opacity
采用Au-Gd混合介质作腔壁,增大腔壁Rosseland不透明度,降低其辐射能耗是提高黑腔辐射温度的途径之一.利用纯Au和Au-Gd混合介质的Rosseland平均辐射不透明度数据库和多次电离区物态方程加入一维辐射流体力学程序,计算分析了在神光-Ⅱ激光装置产生的黑腔X光辐射能源条件下,Au-Gd混合介质作腔壁对提高黑腔辐射温度的影响,得到了Au-Gd混合介质作腔壁可使黑腔辐射温度提高0.1~0.2MK的结论.
黑腔辐射温度 辐射不透明度 Au-Gd混合介质 Hohlraum radiation temperature Opacity Au-Gd mixture 强激光与粒子束
2004, 16(10): 1267
