低相变阈值金属高压加载下的相变层裂特性

采用激光速度干涉仪（VISAR）和X光联合测试技术,在冲击压力远高于相变应力加载下,实验研究低相变阈值金属FeMnNi合金的相变层裂特性,结果发现等厚对称碰撞加载下FeMnNi合金出现反常的层裂行为。针对该反常的层裂行为,利用塑性波、相变波、稀疏波和逆相变引发的稀疏冲击波的相互作用过程进行分析,结果表明,该实验状态下FeMnNi合金样品存在相变和逆相变行为,逆相变引发的稀疏冲击波是导致反常层裂行为的主要因素。     

FeMnNi合金高压相变波形测量和层裂机理分析

采用激光速度干涉仪（VISAR）测试技术,利用逆向加载装置FeMnNi飞片／LiF缓冲层／LiF窗口,对低相变阈值金属FeMnNi合金高压加卸栽历程进行实验研究,结果发现FeMnNi合金在高压加载下发生α→ε相变,在高压卸载下发生ε→γ和γ→α逆相变,并有相应的稀疏冲击波Rs1和Rs2形成。应用该结果分析FeMnNi合金等厚对称在高压加载下的“反常”层裂行为发现,逆相变γ→α引发的稀疏冲击波Rs2与中心稀疏波R的相互作用是导致该“反常”层裂的主要因素。     

FeMnNi合金冲击加卸载历程研究

采用激光速度干涉仪(VISAR),应用逆向加载实验装置FeMnNi飞片/蓝宝石窗口和FeMnNi飞片/LiF缓冲层/LiF窗口,分别对低相变阈值金属FeMnNi合金含相变的低压和高压冲击加卸载历程进行实验研究。参阅文献[3,4]分析了实验结果。在低压加载下,FeMnNi合金样品存在α→ε相变,卸载时存在逆相变ε→α及逆相变引发的卸载稀疏冲击波;在高压加载下,FeMnNi合金样品存在α→ε相变,卸载时可能存在逆相变ε→γ和γ→ε行为及逆相变引发的卸载稀疏冲击波。     

HR2钢及几种铁基材料的冲击相变行为

利用双灵敏度VISAR测量了抗氢钢HR2、工业纯铁DT2和铁锰镍合金FeMnNi在一维应变冲击载荷下的自由面速度历史,结合受载样品的回收分析对其动载行为和断裂表现进行了分析。研究表明,在实验加载压力范围内DT2和FeMnNi样品的自由面速度历史呈现包括相变波在内的典型三波结构,而对HR2钢,尽管金相分析显示其加载前后样品的相组织已发生变化,但速度剖面呈现的仅是典型的弹塑性双波结构。分析认为溶质材料成分和初始相组织是无相变波的主要原因。从冲击相变和卸载逆相变角度解释了在等厚靶碰撞时DT2和FeMnNi材料中出现的多重层裂、浅表层裂现象。     

Influence of Phase Transition on Spalling Behavior in FeMnNi alloy

通过逆向加载和等厚对称碰撞实验相结合的方法,确定了FeMnNi合金完整的加卸载物理过程和相变层裂特征。采用修正的Boettger模型与非平衡两相相变理论模型,成功模拟再现了实验过程,解释了冲击相变、卸载逆相变及稀疏冲击波形成的物理机理。实验和数值模拟相结合,从应力波相互作用的角度定量分析了层裂发生的原因,指出层裂发生的机制正是由于受载样品发生了冲击相变和卸载逆相变。     

冲击相变对FeMnNi合金层裂行为影响研究

通过逆向加载和等厚对称碰撞实验相结合的方法,确定了FeMnNi合金完整的加卸载物理过程和相变层裂特征。采用修正的Boettger模型与非平衡两相相变理论模型,成功模拟再现了实验过程,解释了冲击相变、卸载逆相变及稀疏冲击波形成的物理机理。实验和数值模拟相结合,从应力波相互作用的角度定量分析了层裂发生的原因,指出层裂发生的机制正是由于受载样品发生了冲击相变和卸载逆相变。      

纯铁材料的冲击相变与"反常"层裂

采用VISAR、X射线衍射和金相处理联合测试分析技术,开展等厚对称碰撞实验,研究了纯铁材料的冲击相变与层裂行为特征。结果发现,冲击加载压力大于纯铁材料相变阈值(13 GPa)时,等厚对称碰撞样品发生反常2次层裂。结合相关文献的实验结果,从应力波相互作用的角度分析了反常层裂形成的原因,指出纯铁材料的冲击相变和卸载逆转变及引发的稀疏冲击波是导致反常2次层裂的物理机制。     

斜波压缩下锡的相变和层裂行为

获取不同热力学路径下锡的动态响应实验数据,是深入研究其相变和损伤物理过程的基础.利用小型磁驱装置CQ-4完成了金属锡的斜波加载实验,获取了锡含有相变和层裂损伤物理信息的实验数据.实验结果显示,在加载段锡依次经历了弹塑性转变和β-γ相变两种物理过程,屈服强度约0.194 GPa,相变压力随着锡厚度的增加从7.54 GPa减小到7.14 GPa.在卸载段出现了明显的层裂损伤,层裂强度约1.1 GPa,与相同加载压力下冲击实验结果有巨大差异,层裂片厚度约0.38 mm.结合由锡的多相Helmholtz自由能计算的多相状态方程、Hayes相变动力学方程和损伤度理论,对斜波压缩实验过程进行一维流体动力学数值模拟,计算结果可以很好描述锡的弹塑性转变、相变和层裂三个物理过程.     

层裂的分形机理及分维和连接阈值的关系

通过对微裂纹连接的动力学分析，提出了描述层裂损伤演化的统计分形模型，指出分形层裂面的形成机理与层裂中微裂纹级串连接的动力学过程密切相关，由此，得到了一种单峰的分维－连接阈值关系，定性解释了分维随专心韧性单峰变化的实验现象。     

钽和LY12铝的高压声速测量

应用两种不同的实验装置钽飞片/LY12铝缓冲层/LiF窗口和钽飞片/LiF窗口,采用逆向碰撞法测量了钽在110~131 GPa冲击压力下的纵波声速。实测的钽的声速结果与文献\[5\]报道的数据有较好的一致性。研究结果表明,作为缓冲层的LY12铝与LiF窗口的阻抗比较接近,使用缓冲层对钽的声速测量结果没有明显影响。实验测量同时获得了LY12铝在110 GPa和131 GPa冲击压力下的纵波声速。结合文献\[4\]的数据表明LY12铝在125～150 GPa冲击压力范围内,纵波声速随冲击压力的增加逐渐降低至体波声速。     

Phase transition and dynamics of iron under ramp wave compression

The ramp wave compression experiments of iron with different thicknesses were performed on the magnetically driven ramp loading device CQ-4. Numerical simulations of this process were done with Hayes multi-phase equation of state (H-MEOS) and dynamic equations of phase transition. The calculated results of H-MEOS are in good agreement with those of shock phase transition, but are different from those under ramp wave compression. The reason for this is that the bulk modulus of the material in the Hayes model and the wave velocity are considered constant. Shock compression is a jump from the initial state to the final state, and the sound speed is related to the slope of the Rayleigh line. However, ramp compression is a continuous process, and the bulk modulus is no longer a constant but a function of pressure and temperature. Based on Murnaghan equation of state, the first-order correction of the bulk modulus on pressure in the Hayes model was carried out. The numerical results of the corrected H-MEOS agree well with those of pure iron in both ramp and shock compression phase transition experiments. The calculated results show that the relaxation time of iron is about 30 ns and the phase transition pressure is about 13 GPa. There are obvious differences between the isentropic and adiabatic process in terms of pressure–specific volume and temperature–pressure. The fluctuation of the sound speed after 13 GPa is caused by the phase transition.     

Shock response of a heavy tungsten alloy

This article describes the results of shock wave experiments performed on a heavy tungsten alloy containing W, Ni, and Fe in the ratio of 92.85:4.9:2.25 by weight. These experiments provide information about the shear strength under compression and tensile strength, as measured by the spall threshold, of this alloy to 24 GPa. The results of these experiments show that: (i) the magnitude of its Hugoniot elastic limit (HEL) is 2.76±0.26 GPa; (ii) this alloy deforms plastically above its HEL and thus retains its shear strength to 24 GPa; (iii) the spall strength of the alloy is found to be 1.9±0.4 GPa and is independent of the impact stress and duration of the shock compression pulse; and (iv) the tensile impedance of the alloy, determined from a new experiment designed to measure this impedance, is 68±10 Gg/m² s.     

铈γ→α相变的室温动态特性

通过试样组件尺寸匹配设计的被动围压SHPB实验,获得了99.8%纯铈在1.7GPa静水压内的、包含γ?α相变和逆相变过渡区的室温动态静水压-体应变连续曲线。研究显示:室温铈γ→α相变是具有明显滞后现象的一级相变,而非以往研究认为的体积跃变的一级相变;相变过渡区的静水压范围是0.8~1.3GPa。逆相变过渡区的静水压范围是0.6~1.1GPa;逆相变过渡区的静水压-体应变曲线滞后于相变过渡区的静水压-体应变曲线0.15GPa静水压;在相变和逆相变过渡区内,静水压-体应变曲线按照约4.2GPa体积模量的线性关系演化;演化机制为γ和α两相均匀混合、静水压驱动两相组份转化。基于该演化机制,构建了描述相变前后和相变过程的静水压-体应变响应的三段线性模型。     

Direct laser-driven ramp compression studies of iron: A first step toward the reproduction of planetary core conditions

The study of iron under quasi-isentropic compression using high energy lasers, might allow to understand its thermodynamical properties, in particular its melting line in conditions of pressure and temperature relevant to Earth-like planetary cores (330–1500 GPa, 5000–8000 K). However, the iron alpha-epsilon solid–solid phase transition at 13 GPa favors shock formation during the quasi-isentropic compression process which can depart from the appropriate thermodynamical path. Understanding this shock formation mechanism is a key issue for being able to reproduce Earth-like planetary core conditions in the laboratory by ramp compression. In this article, we will present recent results of direct laser-driven quasi-isentropic compression experiments on iron samples obtained on the LULI 2000 and LIL laser facilities.     

单晶与纳米多晶锡层裂的分子动力学研究

低熔点金属的层裂是目前延性金属动态断裂的基础科学问题之一。采用非平衡态分子动力学方法模拟了冲击压力在13.5～61.0 GPa下单晶和纳米多晶锡的经典层裂和微层裂过程。研究结果表明：在加载阶段,冲击速度不影响单晶模型中的波形演化规律,但影响纳米多晶模型中的波形演化规律,其中经典层裂中晶界滑移是影响应力波前沿宽度的重要因素;在单晶模型中,经典层裂和微层裂中孔洞成核位置位于高势能处;在纳米多晶模型中,经典层裂中的孔洞多在晶界（含三晶界交界处）处成核,并沿晶定向长大,产生沿晶断裂,而微层裂中孔洞在晶界和晶粒内部成核,导致沿晶断裂、晶内断裂和穿晶断裂;孔洞体积分数呈现指数增长,相同冲击速度下单晶和纳米多晶Sn孔洞体积分数变化规律一致;经典层裂中孔洞体积分数曲线的两个转折点分别表示孔洞成核与长大的过渡和材料从损伤到断裂的灾变性转变。     

Ab initio investigation of a possible liquid–liquid phase transition in MgSiO3 at megabar pressures

We perform density functional molecular dynamics simulations of liquid and solid MgSiO₃ in the pressure range of 120–1600 GPa and for temperatures up to 20,000 K in order to provide new insight into the nature of the liquid–liquid phase transition that was recently predicted on the basis of decaying laser shock wave experiments [Phys. Rev. Lett. 108 (2012) 065701]. However, our simulations did not show any signature of a phase transition in the liquid phase. We derive the equation of state for the liquid and solid phases and compute the shock Hugoniot curves. We discuss different thermodynamic functions and by explore alternative interpretations of the experimental findings.