Articles in press have been peer-reviewed and accepted, which are not yet assigned to volumes /issues, but are citable by Digital Object Identifier (DOI).
Display Method:
2020, 34(1).  
2020, 34(1).  
PDF (0)
Physical Property & Structure
The dynamics of phase transition of tin under ramp wave loading was studied with experiment and simulation. The ramp wave compression experiment of tin was carried out with photonic Doppler velocimetry (PDV) and compact pulsed power generator CQ-4. The velocity wave profiles obtained experimentally show that tin undergoes physical processes such as elastoplastic transition and phase transition in the loading section, and the phase transition pressure is about 7.5 GPa. As the increase of thickness of tin, the characteristic velocity corresponding to the onset of phase transition decreased slightly from 676.3 m/s to 636.8 m/s, and the corresponding pressure was from 7.62 GPa to 7.11 GPa. The Hayes multi-phase equation of state and non-equilibrium phase transition kinetic model were employed to simulate the experimental process, and the numerical results can well describe the physical processes such as elastoplastic transformation and phase transformation in the loading section. The calculated results revealed that the correction of the bulk modulus with pressure needed to be considered under ramp wave compression. The influence of typical physical parameters, such as phase transition relaxation time and bulk modulus, on the velocity waveform was discussed. The results show that phase transition relaxation time and initial free energy mainly affect the velocity waveform in the mixing zone, the bulk modulus of the two phases affect the velocity waveform after phase transition and overall velocity waveform respectively.
Based on the first principle of density functional theory, the crystal structure of MgN8 was predicted in the pressure range of 0–100 GPa by using CALYPSO structure search technique and VASP software. After systematically studying the predicted structure, it was found that the enthalpy of α-MgN8 crystal with space group P4/mbm was the lowest at ambient pressure. The phase was changed to β-MgN8 phase of P4/mnc and γ-MgN8 phase of Cmcm when the pressure reached 24.3 GPa and 68.3 GPa, respectively. And both of the phase transitions were the first order phase transition of corresponding volume collapse. The calculated results of electronic properties suggested that the existence of a band gap of 3.09 eV between the conduction band and valence band of α-MgN8 phase revealed the non-gold properties of the structure, whereas the obvious metal characteristics appeared in the β-MgN8 phase and γ-MgN8 phase. Bader charge transfer calculation showed that the charge which transferred from Mg atom to N atom, increased gradually with the increase of pressure.
The effect of rapid compression on the stability of olivine structure was studied in this work. In the first group, the olivine samples were rapidly compressed to 3 GPa at 293, 373, 473, 573, 673 and 773 K respectively. In the second group, the olivine samples were sintered for 2 h at 873, 973, 1 073 and 1 173 K and then were rapidly compressed to 3 GPa at room temperature. The structure of the recovered samples were analyzed by synchrotron radiation X-ray diffraction, Raman spectroscopy, infrared absorption spectrum and scanning electron microscopy. These results showed that the structure of olivine was stable and there were no phase transition caused by temperature and rapid compression. The micromorphology observation of recovered olivine indicated that the grains were refined. Due to the residual stress and grain refinement in the recovered samples, the Raman vibrational peaks of olivine (822 cm–1 and 854 cm–1 at room temperature) showed some broadening and displacement.
Based on density functional theory, a ZrBeO3 crystal model of perovskite structure was constructed. The binding energy of the crystal model was calculated, and the thermodynamic stability of the structure was calculated. The elastic constant of the structure under different pressures was calculated, and ZrBeO3 was calculated according to it. The bulk modulus, shear modulus, Young’s modulus, Poisson’s ratio, BH/GH and other parameters, the calculation results show that the material has mechanical stability, and the material changes from brittle to ductile with increasing isostatic pressure; the hardness of ZrBeO3 under zero pressure is 34.5 GPa, which indicates that the crystal should be superhard material. The calculated phonon energy spectrum show that ZrBeO3 is thermodynamically unstable under low temperature and zero pressure. The phonon spectrum, different atomic orbitals and chemical bond values at different pressures show that the Be-O covalent bond formed by the impurity of Be atom is enhanced and the Zr-O bond ion bond component is enhanced with the increase of pressure. The lattice dynamics tend to be stable.
High entropy alloy (HEA) has high strength, high hardness, high wear resistance and corrosion resistance which traditional alloys do not have, and has broad application prospects. The mechanical properties of AlCrFeCuNi high Entropy Alloy (HEA) under axial loading were also studied in this paper. Molecular dynamics method was used to simulate the experimental preparation process of HEA and establish an atomic model. The mechanical properties of AlCrFeCuNi HEA at different temperatures and Al concentrations were studied. The deformation process and the reasons for its high plasticity were analyzed from the point of view of material science. The simulation results show that the AlCrFeCuNi HEA undergoes elastic deformation, yield and plastic deformation stages under tension loads. In the yield stage, the appearance and growth of twins and stacking faults are one of the main reasons for the uneven plastic deformation of the alloy. The analysis shows that the Young’s modulus and yield stress of the HEA decrease linearly with the increase of Al concentration. The HEA have strong temperature effect. The lower the temperature, the smaller the Al concentration, and the greater the decrease in Young’s modulus and yield stress.
Theory and Calculation
This study investigated the applicability of three p-\begin{document}$\alpha $\end{document} models and p-\begin{document}$\lambda $\end{document} model for predicting shock compaction response of heterogeneous W-Cu powder mixture. Mie-Grüneisen method and Barry isobaric mixing method were employed to predict the Hugoniot of W-Cu powder mixture with the same porosity based on the Hugoniot relationships. At high pressure section, the results were in good agreement with the experimental results, but it deviated greatly at the low pressure section. The p-\begin{document}$\alpha $\end{document} models and p-\begin{document}$\lambda $\end{document} model were applied to fit the experimental results, and it was found that all the other models were able to describe the shock compression response of W-Cu powder mixture except p-\begin{document}$\alpha $\end{document} PL model. The crush strength and compression path of all models are different due to selection of empirical parameters, and they are with poor prediction function.
High-speed particle-laden flow has important applications in astronomy, natural disasters, industrial safety, medical industry, and national defense. In this work, a direct numerical simulation method based on the stratified flow model is used to study the interaction between a planar shock wave and an elliptical column cloud. The influence of the aspect ratio and the tilt angle, the distributions of the flow velocity, RMS velocities along x axis, kinetic energy, internal energy, and turbulent kinetic energy are analyzed; energy values in the upstream region, the elliptical column cloud region and the downstream region of the computational domain are quantitatively analyzed. The 1-D volume-average model is improved for elliptical columns. Based on this model, the appropriate artificial effective drag coefficients are decided by fitting the positions of the reflected shock and the transmitted shock from the direct numerical simulation results, and the distribution of the optimal artificial effective drag coefficients is also discussed.
Dynamic Response of Materials
The high-speed gun is used to study the impact of quartz glass ball on rigid target plate. The crushing process and failure mode of the ball at different speeds are analyzed. When the impact velocity is lower than the critical failure velocity, the quartz glass ball rebounds from the target plate, and the rebounding speed is slightly below the original speed; when the critical speed is exceeded, the sphere exhibits a “compressed fracture zone–surface spalling zone–shear failure zone” failure structure; further increasing the collision velocity, the expansion of the shear failure zone causes the sphere to be fragmented into several “crescent” fragments. At higher impact speeds, the quartz glass ball collapses and spalls at a distance away from the impact end. Furthermore, the discrete element software is utilized to simulate the impact damage process of the sphere. The crushing of the sphere under high-speed collision can be divided into three stages: elastic compression, integral crushing, secondary impact. Before the ball breaks, the Hertz contact theory can describe its impact force well, but the crushing force is much smaller than the theoretical value due to the fracture unloading, and the deviation gradually increases with the increasing impact speed.
Nacre inspired composite materials with different assembly modes were fabricated by photocurable 3D printing. The composite materials consist of two kinds of matrix materials. The tension mechanical properties, fracture and energy dissipation mechanism were analyzed by quasi-static tensile tests combined with scanning electron microscope (SEM). The results show that, keeping the length of the cell constant, the strength of nacre inspired composite materials increase linearly, while the fracture strain decreases linearly with the increasing of in-plane assembly angle. The fracture strain decreases linearly with the increasing of out-plane assembly angle. When the out-plane assembly angle is less than 45°, the strength of nacre inspired composite materials increases linearly with increasing such angle, but it tends to be stable when such angle exceeds 45°. The strength of the material reaches the maximum value when the out-plane assembly angle is 45°. Most of the tension energy is dissipated by pull-out of the hard materials, generation, propagation and combination of micro-cracks at the soft/hard interface and the crack deflection in the propagation process.
In order to study the dynamic response of reinforced concrete wall under impact load, a finite element model of reinforced concrete wall is established by means of ANSYS/LS-DYNA. The impact mass is 2 t and the impact velocity is 3 m/s. The effects of axial compression ratio, wall width and boundary elements on the impact resistance of reinforced concrete walls are analyzed. On this basis, the three stages of wall failure under extreme loading conditions are analyzed, and a criterion of evaluating wall failure under extreme loading is proposed. The influence of axial compression ratio, wall width and boundary elements under extreme loading is analyzed by using the proposed criterion. The results show that, in a certain range, with the increase of the axial compression ratio, the impact resistance of the wall is improved, and the damage area of the wall with axial compression is concentrated. Increasing the wall width and adding edge components can effectively enhance the impact resistance of the wall. Under the ultimate load. When the impact mass is constant, the impact energy required for structural failure decreases with the increasing axial compression ratio.
High Pressure Applications
In order to explore the influence of the scale effects on the timing of fragmentation and shock wave, the key parameters affecting the location of fragmentation and shock wave are determined by the dimensionless analysis and explosion theory for the prefabricated fragment warhead. This paper proposes a method to predict the timing relationship of the prototype warhead fragmentation and blast wave by the scale ratio warhead, and establishes the model of the warhead under different scale ratios. The numerical simulation is carried out with ANSYS/LS-DYNA finite element software. Based on the theoretical and numerical results, we analyze the scale effects of the warhead on the timing of shock waves and fragmentation. The results show that the ratio of the encounter position of fragments and shock waves produced by the scaled model and the prototype model depends on the mass ratio of the two models. Without considering the velocity attenuation of fragments, the ratio of the encounter position in two models is equal to the 0.33 power of the mass ratio. Due to the effects of fragmentation velocity attenuation, the method is applicable to models with a mass reduction ratio of not less than 0.2.
The state equation of water, artificial viscosity coefficient and mesh size have a great influence on the numerical results of underwater explosion shock wave. In order to improve the simulation accuracy of underwater explosion shock wave, the peak pressure and specific impulse of the conventional TNT explosive underwater explosion are taken as the measurement indicators, and the influence of these factors on the numerical simulation results is studied. For the five kinds commonly state equations of water, the specific values of the artificial viscosity coefficients under different working conditions and appropriate grid size for different explosive equivalents are given. These parameters can provide reference for improving simulation accuracy of underwater explosion shock wave under different working conditions. First, through a series of simulations of the commonly used five kinds of state equations of water, the calculation results of peak pressure and specific impulse are compared with the empirical formula, and the error analysis is carried out to give the applicable scope of each state equation. Secondly, the influence of the artificial viscosity coefficient on the calculation results is discussed, and a series of calculations are carried out for the primary and secondary artificial viscosity coefficients under different working conditions. The recommended range of values for the primary and secondary artificial viscosity coefficients under different working conditions is given. Finally, through a series of calculations on 0.1, 0.5, 1, 10, 50, 100, 500 and 1 000 kg equivalent explosives and different grid sizes, the recommended mesh sizes corresponding to different explosive equivalents under the requirement of engineering calculation accuracy are obtained by limiting the relative error of peak pressure less than 10%. The expressions of the recommended mesh sizes corresponding to different explosive equivalents are also given.
The essence of supercavitating projectile penetration is the dynamic response of a special underwater structure subjected to high-speed impact load. In this paper, the damage effect of 12.7 mm supercavitating projectile penetrating typical underwater target shell is studied. Based on LS-DYNA finite element analysis software, the equivalent model of supercavitating projectile penetrating into curved surface target vertically in water environment is established. The combined damage effect of kinetic energy penetration and bubble collapse on target plate during penetration is simulated, and the stress variation and structural deformation law of target plate at different stages are obtained. The results show that the peak pressure of water medium on the head surface reaches 768 N when the velocity of projectile is 200 m/s before penetrating the target, and the surface of the target exhibits obvious concave deformation; with projectile kinetic energy penetration and bubble collapse impact during penetrating process, the impact effect of water medium is less than 2% of that by kinetic energy penetration. After penetrating the target, a water jet with a peak velocity of 42 m/s is formed on the front of the target and further acts on the break. The overall bending deformation of the target plate occurs. In the range of 200 m/s to 300 m/s, the bending deformation decreases with the increase of projectile impact velocity. Ductile perforation occurs locally on the target plate, and the projectile has better perforation effect in water environment. The change of projectile velocity has little effect on the size of the perforation.
In order to study the effect of nose cabin on projectile low speed and high mass during the penetration of metal plates, a finite element analysis model of blunt projectile with nose cabin was established. Based on the mechanical properties, nose cabin can be regarded as equivalent to light foam aluminum material. Numerical simulation of blunt projectile with nose cabin penetrates into metal plates under different working conditions were implemented. The progress of projectile with nose cabin penetrates into metal plate was analyzed. The difference between residual velocity of blunt projectile with and without nose cabin was compared. The results show that there are significant differences in the progress of projectiles penetration into metal plates between blunt projectiles with and without nose cabin. Nevertheless, the failure modes for both conditions are similar. The yield stress of equivalent material of nose cabin has limited influence on penetrative performance of projectile. In conclusion, nose cabin can bring very limited improvement to the penetration capability of blunt projectile, and the effect of nose cabin can be neglected in practical engineering applications.
CH4-H2 mixture explosion experiments were performed in a 20 L spherical explosion vessel with the equivalence ratio of 1. Gas proportion and ignition energy were varied to explore their effects on the explosion pressure and intensity. It is found that higher hydrogen proportion causes higher explosion shock wave propagation speed, while the ignition energy has little effects on the explosion shock wave propagation speed. Higher ignition energy can enhance the explosion overpressure, and this enhancement effect is remarkable when the hydrogen proportion is lower, and is not evident when the hydrogen proportion is higher. The effect of ignition energy on the explosion severity index KG is not evident, but the effect of hydrogen proportion on KG is remarkable. The positive effect of hydrogen addition on KG is very slight at low hydrogen proportion while it becomes much more pronounced at higher hydrogen contents. Furthermore, the explosion intensity of hydrogen is approximately tenfold of that of methane explosion with corresponding same equivalent ratio, and therefore, the presence of hydrogen will greatly enhance the explosion hazard of methane.
Lithium-ion battery separators act as the physical barriers to prevent contact between the positive and negative electrodes, and their structural integrity is critical to battery safety. In this paper, uniaxial tensile tests were carried out on four kinds of commercial separators, and the effects of loading angle and linear notch on tensile strength, elastic modulus and fracture mode were analyzed. The results show that the tensile strength of the 0° specimens without notch is the largest and the tensile strength of 90° specimens is the smallest. When the loading angles of two notched specimens are supplementary, their tensile strength is close to each other. For the notched specimens, the failure load is the largest when the notched direction is along 90°. The linear notched specimens have higher elastic modulus, but the plastic deformation is greatly reduced. Both the unnotched specimens and the notched specimens are broken along MD (machine direction) except for the 0° specimens along TD (transverse direction).
Experimental Study of the Effect of Shear Stress on Phase Transition in c-Axis CdS Single Crystal under Dynamic Loading
TANG Zhi-Ping, Gupta Y M
1989, 3(4): 290-297 .   doi: 10.11858/gywlxb.1989.04.005
Abstract(4697) PDF(215)
The Generation of 90 GPa Quasi-Hydrostatic Pressures and the Measurements of Pressure Distribution
LIU Zhen-Xian, CUI Qi-Liang, ZOU Guang-Tian
1989, 3(4): 284-289 .   doi: 10.11858/gywlxb.1989.04.004
Abstract(5273) PDF(339)
Development of Large Volume-High Static Pressure Techniques Based on the Hinge-Type Cubic Presses
WANG Hai-Kuo, HE Duan-Wei, XU Chao, GUAN Jun-Wei, WANG Wen-Dan, KOU Zi-Li, PENG Fang
2013, 27(5): 633-661.   doi: 10.11858/gywlxb.2013.05.001
Abstract(4553) PDF(188)
A Study on Calculation of the Linear Thermal Expansion Coefficients of Metals
ZHENG Wei-Tao, DING Tao, ZHONG Feng-Lan, ZHANG Jian-Min, ZHANG Rui-Lin
1994, 8(4): 302-305 .   doi: 10.11858/gywlxb.1994.04.010
Abstract(6530) PDF(302)
Long-Distance Flight Performances of Spherical Fragments
TAN Duo-Wang, WEN Dian-Ying, ZHANG Zhong-Bin, YU Chuan, XIE Pan-Hai
2002, 16(4): 271-275 .   doi: 10.11858/gywlxb.2002.04.006
Abstract(4919) PDF(173)
Numerical Simulation of the Interactions between Hyperpressure Waterjet and Explosive
HE Yuan-Hang, LI Hai-Jun, ZHANG Qing-Ming
2005, 19(2): 169-173 .   doi: 10.11858/gywlxb.2005.02.012
Abstract(4876) PDF(157)
Chemical Synthesis and Characterization of Flaky h-CN by HPHT
YANG Da-Peng, LI Ying-Ai, DU Yong-Hui, SU Zuo-Peng, JI Xiao-Rui, YANG Xu-Xin, GONG Xi-Liang, ZHANG Tie-Chen
2007, 21(3): 295-298 .   doi: 10.11858/gywlxb.2007.03.013
Abstract(5369) PDF(181)
The Failure Strength Parameters of HJC and RHT Concrete Constitutive Models
ZHANG Ruo-Qi, DING Yu-Qing, TANG Wen-Hui, RAN Xian-Wen
2011, 25(1): 15-22 .   doi: 10.11858/gywlxb.2011.01.003
Abstract(7601) PDF(207)
Detonation Shock Dynamics Calibration of JB-9014 Explosive at Ambient Temperature
TAN Duo-Wang, FANG Qing, ZHANG Guang-Sheng, HE Zhi
2009, 23(3): 161-166 .   doi: 10.11858/gywlxb.2009.03.001
Abstract(5263) PDF(176)
Phase Evolution of Zr-Based Bulk Metallic Glass Prepared by Shock-Wave Quenching under High Temperature and High Pressure
YANG Chao, CHEN Wei-Ping, ZHAN Zai-Ji, JIANG Jian-Zhong
2007, 21(3): 283-288 .   doi: 10.11858/gywlxb.2007.03.011
Abstract(5108) PDF(168)
Design and Temperature Calibration for Heater Cell of Split-Sphere High Pressure Apparatus Based on the Hinge-Type Cubic-Anvil Press
CHEN Xiao-Fang, HE Duan-Wei, WANG Fu-Long, ZHANG Jian, LI Yong-Jun, FANG Lei-Ming, LEI Li, KOU Zi-Li
2009, 23(2): 98-104 .   doi: 10.11858/gywlxb.2009.02.004
Abstract(5459) PDF(187)
Experiment and Numerical Simulation of Cylindrical Explosive Isostatic Pressing
CHEN Lang, LU Jian-Ying, ZHANG Ming, HAN Chao, FENG Chang-Gen
2008, 22(2): 113-117 .   doi: 10.11858/gywlxb.2008.02.001
Abstract(4932) PDF(142)
Activities of Antioxidative Enzymes and the Responds to Cold Stress of Rice Treated by High Hydrostatic Pressure
BAI Cheng-Ke, LI Gui-Shuang, DUAN Jun, PENG Chang-Lian, WENG Ke-Nan, XU Shi-Ping
2005, 19(3): 235-240 .   doi: 10.11858/gywlxb.2005.03.008
Abstract(5010) PDF(145)
Application Research on JWL Equation of State of Detonation Products
ZHAO Zheng, TAO Gang, DU Chang-Xing
2009, 23(4): 277-282 .   doi: 10.11858/gywlxb.2009.04.007
Abstract(5813) PDF(178)
Discussions on the VLW Equation of State
LONG Xin-Ping, HE Bi, JIANG Xiao-Hua, WU Xiong
2003, 17(4): 247-254 .   doi: 10.11858/gywlxb.2003.04.002
Abstract(4892) PDF(190)
Numerical Simulation of Hypervelocity Launch of Flier Plate with Gradual Change Impedance
CHEN Lang, LIU Qun, LU Jian-Ying, GONG Zi-Zheng, GUO Xin-Wei
2009, 23(3): 167-172 .   doi: 10.11858/gywlxb.2009.03.002
Abstract(5057) PDF(168)
Effects of Liner Curvature Radius on Formation of Double-Layered Spherical Segment Charge Liner into Tandem Explosively Formed Projectile (EFP)
ZHENG Yu, WANG Xiao-Ming, LI Wen-Bin, LI Wei-Bing
2009, 23(3): 229-235 .   doi: 10.11858/gywlxb.2009.03.011
Abstract(5601) PDF(179)
Analysis of Equivalence for Structural Response Induced by Pulsed X-Ray with Other Analogue Sources
PENG Chang-Xian
2002, 16(2): 105-110 .   doi: 10.11858/gywlxb.2002.02.004
Abstract(4909) PDF(248)
Studies on the Distribution of Breakdown Liquid Particle Size under Explosive Detonation
HU Dong, HAN Zhao-Yuan, ZHANG Shou-Qi, ZHAO Yu-Hua, WANG Bing-Ren, CHEN Jun, SUN Zhu-Mei, CAI Qing-Jun, YAO Jiu-Cheng, DONG Shi
2008, 22(1): 6-10 .   doi: 10.11858/gywlxb.2008.01.002
Abstract(6057) PDF(155)
Effect of Boron Contained in the Catalyst on Thermal Stability of Boron-Doped Diamond Single Crystals
WANG Mei, LI He-Sheng, LI Mu-Sen, GONG Jian-Hong, TIAN Bin
2008, 22(2): 215-219 .   doi: 10.11858/gywlxb.2008.02.017
Abstract(5017) PDF(171)
A Kind of Anodized Aluminium Shock Wave Detectors
SUN Yue, YUAN Chang-Ying, ZHANG Xiu-Lu, WU Guo-Dong
2004, 18(2): 157-162 .   doi: 10.11858/gywlxb.2004.02.011
Abstract(5087) PDF(141)
Comment on the Pressure Gauge for the Experiments at High Temperature and High Pressure with DAC
ZHENG Hai-Fei, SUN Qiang, ZHAO Jin, DUAN Ti-Yu
2004, 18(1): 78-82 .   doi: 10.11858/gywlxb.2004.01.014
Abstract(5029) PDF(187)
The Launching Technique of Hypervelocity Projectiles in Two-Stage Light Gas Gun
WANG Jin-Gui
1992, 6(4): 264-272 .   doi: 10.11858/gywlxb.1992.04.004
Abstract(6878) PDF(218)
Failure Modes of Ductile Metal Plates under Normal Impact by Flat-Ended Projectiles
PAN Jian-Hua, WEN He-Ming
2007, 21(2): 157-164 .   doi: 10.11858/gywlxb.2007.02.007
Abstract(4847) PDF(191)
Investigation of in Situ Raman Spectrum and Electrical Conductivity of PbMoO4 at High Pressure
YU Cui-Ling, YU Qing-Jiang, GAO Chun-Xiao, LIU Bao, HE Chun-Yuan, HUANG Xiao-Wei, HAO Ai-Min, ZHANG Dong-Mei, CUI Xiao-Yan, LIU Cai-Long, et al.
2007, 21(3): 259-263 .   doi: 10.11858/gywlxb.2007.03.007
Abstract(4741) PDF(165)
Experimental Validation of Quasi-Elastic Response of Metal during Reloading Process
SONG Ping, ZHOU Xian-Ming, YUAN Shuai, LI Jia-Bo, WANG Xiao-Song
2007, 21(3): 327-331 .   doi: 10.11858/gywlxb.2007.03.019
Abstract(4731) PDF(156)
Shock Wave Physics: The Coming Challenges and Exciting Opportunities in the New Century-Introduction of the 12th International Conference of Shock Compression of Condensed Matter (SCCM-2001)
GONG Zi-Zheng
2002, 16(2): 152-160 .   doi: 10.11858/gywlxb.2002.02.012
Abstract(4834) PDF(204)
Two-Dimensional Numerical Simulation of Explosion for Premixed CH4-O2-N2 Mixture
LI Cheng-Bing, WU Guo-Dong, JING Fu-Qian
2009, 23(5): 367-376 .   doi: 10.11858/gywlxb.2009.05.008
Abstract(4655) PDF(184)
Evaluation for Uncertainty of Particle Velocity in Hugoniot Measurements
DAI Cheng-Da, WANG Xiang, TAN Hua
2005, 19(2): 113-119 .   doi: 10.11858/gywlxb.2005.02.003
Abstract(5031) PDF(169)
Structure and Ferroelectric Properties of Dense Nanocrystalline BaTiO3 Ceramics Prepared by High Pressure Sintering Method
LI Peng-Fei, JIN Chang-Qing, XIAO Chang-Jiang, PAN Li-Qing, WANG Xiao-Hui
2007, 21(3): 249-252 .   doi: 10.11858/gywlxb.2007.03.005
Abstract(4817) PDF(160)
In-Situ High-Pressure X-Ray Diffraction of Natural Beryl
QIN Shan, LIU Jing, LI Hai-Jian, ZHU Xiang-Ping, LI Xiao-Dong
2008, 22(1): 1-5 .   doi: 10.11858/gywlxb.2008.01.001
Abstract(5200) PDF(170)
Isothermal Equations of State of Au and Pt at Room Temperature: Implication for Pressure Scales
JIN Ke, WU Qiang, LI Xin-Zhu, CAI Ling-Cang, JING Fu-Qian
2009, 23(3): 181-188 .   doi: 10.11858/gywlxb.2009.03.004
Abstract(4916) PDF(162)
Factors Analysis of Debris Cloud's Shape of Hypervelocity Impact
TANG Mi, BAI Jing-Song, LI Ping, ZHANG Zhan-Ji
2007, 21(4): 425-432 .   doi: 10.11858/gywlxb.2007.04.016
Abstract(4629) PDF(160)
Effect of Pressure on Carbon Concentration in C-H-O Supercritical-Fluid
ZHAO Xian-Feng, HONG Shi-Ming, LIU Fu-Sheng
2003, 17(2): 101-105 .   doi: 10.11858/gywlxb.2003.02.004
Abstract(5121) PDF(164)
Phase Transformation Mechanism of Single Crystal Iron from MD Simulation
CUI Xin-Lin, ZHU Wen-Jun, HE Hong-Liang, DENG Xiao-Liang, LI Ying-Jun
2007, 21(4): 433-438 .   doi: 10.11858/gywlxb.2007.04.017
Abstract(4476) PDF(155)
Response of Homemade PVDF Piezofilm under Shock Loading and Unloading
LI Yan, ZHANG Xiang-Rong, TAN Hong-Mei, LIU Xiao-Ling, PEI Ming-Jing
2004, 18(3): 261-266 .   doi: 10.11858/gywlxb.2004.03.011
Abstract(5350) PDF(230)
Research on Using Raman Spectra of Carborundum Anvil as Pressure Sensor at Pressure of 0.1~3 000 MPa
QU Qing-Ming, ZHENG Hai-Fei
2007, 21(3): 332-336 .   doi: 10.11858/gywlxb.2007.03.020
Abstract(4904) PDF(236)
Shock-Activating and Sintering of Hydroxyapatite Agglomerate
LIAO Qi-Long, YANG Shi-Yuan, CAI Ling-Cang, ZHENG Chang-Qiong
2003, 17(3): 209-213 .   doi: 10.11858/gywlxb.2003.03.009
Abstract(4696) PDF(335)
Acoustic Velocity of Water under High Temperature and High Pressure: Validity of the Equation of State of Water
LI Fang-Fei, CUI Qi-Liang, LI Min, ZHOU Qiang, ZOU Guang-Tian
2008, 22(3): 281-285 .   doi: 10.11858/gywlxb.2008.03.010
Abstract(4879) PDF(163)
Perimeter-Area Relation of Fractal Island
1990, 4(4): 259-262 .   doi: 10.11858/gywlxb.1990.04.004
Abstract(4876) PDF(209)
Application of Fiber Velocity Interferometer System for Any Reflector in High Pressure Physics
WENG Ji-Dong, TAN Hua, CHEN Jin-Bao, JIA Bo, HU Shao-Lou, MA Yun, WANG Xiang
2004, 18(3): 225-230 .   doi: 10.11858/gywlxb.2004.03.006
Abstract(5144) PDF(235)
Shock Wave Compression of PZT 95/5 Ferroelectric Ceramic
LIU Gao-Min, DU Jin-Mei, LIU Yu-Sheng, TAN Hua, HE Hong-Liang
2008, 22(1): 30-34 .   doi: 10.11858/gywlxb.2008.01.007
Abstract(4879) PDF(160)
Ultrasonic Measurement and Isothermal Equation of State for LY12Al under Static Pressures
ZHANG Ting, BI Yan, ZHAO Min-Guang
2005, 19(1): 35-40 .   doi: 10.11858/gywlxb.2005.01.007
Abstract(4705) PDF(151)
Analysis on the Influence of Multi-Layered Media on Stress Wave Propagation
DONG Yong-Xiang, HUANG Chen-Guang, DUAN Zhu-Ping
2005, 19(1): 59-65 .   doi: 10.11858/gywlxb.2005.01.011
Abstract(4604) PDF(165)
Synthesis and Characterization of h-BCN Nanocrystallite under High-Pressure and High-Temperature
LI Xue-Fei, ZHANG Jian, SHEN Long-Hai, YANG Da-Peng, CUI Qi-Liang, ZOU Guang-Tian
2007, 21(3): 237-241 .   doi: 10.11858/gywlxb.2007.03.003
Abstract(4507) PDF(182)
A Study of the Intensity High Density Polyethylene at Static High Pressure
YANG Guang-Qun, WANG Hui, WU Rui-Qi
1992, 6(3): 230-234 .   doi: 10.11858/gywlxb.1992.03.012
Abstract(1951) PDF(13)
An Approximate Relation between Cubical Thermal Expansion Coefficient of Solid and Pressure
YAN Zu-Tong
2000, 14(4): 253-256 .   doi: 10.11858/gywlxb.2000.04.003
Abstract(5483) PDF(508)
Electrical Conductivity and X-Ray Diffraction Study of Iron under High Pressures
HUANG Wei-Jun, CUI Qi-Liang, BI Yan, ZHOU Qiang, ZOU Guang-Tian
2007, 21(1): 40-44 .   doi: 10.11858/gywlxb.2007.01.007
Abstract(4748) PDF(192)
Thermodynamic Analysis of Diamond Growth with Catalyst at HPHT
XU Bin, LI Li, TIAN Bin, FAN Xiao-Hong, FENG Li-Ming
2009, 23(3): 189-195 .   doi: 10.11858/gywlxb.2009.03.005
Abstract(4870) PDF(176)
Two-Dimensional Simulation of Transient Detonation Process for H2-O2-N2 Mixture
DONG Gang, FAN Bao-Chun, XIE Bo
2004, 18(1): 40-46 .   doi: 10.11858/gywlxb.2004.01.008
Abstract(4554) PDF(170)
Molecular Analysis of Stable Mutagenesis Rice Cultivar Induced by High Hydrostatic Pressure
SHEN Si-Le, XU Shi-Ping, WENG Ke-Nan, TAN Mei, ZHANG Jian-Feng, LONG Guo-Hui, JIA Xiao-Peng, CHI Yuan-Bin, LIU Bao, ZOU Guang-Tian
2004, 18(4): 289-294 .   doi: 10.11858/gywlxb.2004.04.001
Abstract(5020) PDF(160)
Modification of Tuler-Butcher Model with Damage Influence
JIANG Dong, LI Yong-Chi, GUO Yang
2009, 23(4): 271-276 .   doi: 10.11858/gywlxb.2009.04.006
Abstract(1984) PDF(25)
Experimental Studies on Air Drag Coefficient of Spherical Tungsten Fragments
TAN Duo-Wang, WANG Guang-Jun, GONG Yan-Qing, GAO Ning
2007, 21(3): 231-236 .   doi: 10.11858/gywlxb.2007.03.002
Abstract(4894) PDF(249)
Effect of High Pressure on Exoproteinase of Bacillus subtilis
XIE Hui-Ming, HUANG Xun-Duan, PAN Jian, ZENG Qing-Mei, WANG Hai-Xiang, JIANG Ye-Lei
2007, 21(1): 95-102 .   doi: 10.11858/gywlxb.2007.01.016
Abstract(4614) PDF(151)
Theoretical Study on High Pressure Liquid Sintering of Polycrystalline Diamond Compact
DENG Fu-Ming, ZHAO Guo-Gang, WANG Zhen-Ting, GUO Gang, LIU Xiao-Hui, CHEN Qi-Wu
2004, 18(3): 252-260 .   doi: 10.11858/gywlxb.2004.03.010
Abstract(2130) PDF(19)
Microwave Radiation Measurement on Hypervelocity Impacts
MA Ping, LIU Sen, HUANG Jie, SHI An-Hua, MIAO Jun-Gang
2008, 22(2): 220-224 .   doi: 10.11858/gywlxb.2008.02.018
Abstract(4711) PDF(249)
Electronic Behaviors of the Rocksalt and Monoclinic AgCl under Pressure
WANG Zuo-Cheng, CHE Li-Xin, LI Yan, CUI Tian, ZHANG Miao, NIU Ying-Li, MA Yan-Ming, ZOU Guang-Tian
2007, 21(3): 225-230 .   doi: 10.11858/gywlxb.2007.03.001
Abstract(4715) PDF(163)
Experimental Study on the Damage Effect of Compound Reactive Fragment Penetrating Diesel Oil Tank
XIE Chang-You, JIANG Jian-Wei, SHUAI Jun-Feng, MEN Jian-Bing, WANG Shu-You
2009, 23(6): 447-452 .   doi: 10.11858/gywlxb.2009.06.008
Abstract(2907) PDF(163)
Study on the Technique of Electric Gun Loading for One Dimensionally Planar Strain
WANG Gui-Ji, ZHAO Jian-Heng, TANG Xiao-Song, TAN Fu-Li, WU Gang, LIU Hai-Tao, KUANG Xue-Wu
2005, 19(3): 269-274 .   doi: 10.11858/gywlxb.2005.03.013
Abstract(4588) PDF(169)
Ferroelectric/Antiferroelectric Phase Transition Studies of PZT-95/5 Ceramics under Shock Loading
LIU Gao-Min, TAN Hua, YUAN Wan-Zong, WANG Hai-Yan, ZHANG Yi
2002, 16(3): 231-236 .   doi: 10.11858/gywlxb.2002.03.013
Abstract(4691) PDF(167)
Equation of state of detonation products for PETN explosive
ZHAO Yan-Hong, LIU Hai-Feng, ZHANG Gong-Mu
2009, 23(2): 143-149 .   doi: 10.11858/gywlxb.2009.02.011
Abstract(4910) PDF(165)
High Temperature and High Pressure Synthesis and Study of 0212-Type Ca3Cu2O4+Cl2-y
YANG Da-Xiao, LIU Qing-Qing, GAO Wei-Bo, YU Wen, LI Feng-Ying, JIN Chang-Qing
2007, 21(1): 15-19 .   doi: 10.11858/gywlxb.2007.01.003
Abstract(4732) PDF(278)
Shock Wave Crystallization of Amorphous Alloys FeSiB, FeMoSiB and FeCuNbSiB
ZHAO He-Yun, KAN Jia-De, WANG Hai, LIU Zuo-Quan
2002, 16(2): 131-136 .   doi: 10.11858/gywlxb.2002.02.008
Abstract(4608) PDF(141)
Study on Standard Cylinder Test Technology and Data Processing Method
SUN Zhan-Feng, LI Qing-Zhong, SUN Xue-Lin, WU Jian-Hua, TANG Tie-Gang
2008, 22(2): 160-166 .   doi: 10.11858/gywlxb.2008.02.009
Abstract(4753) PDF(173)
Numerical Simulation of Craters Produced by Projectile Hypervelocity Impact on Aluminum Targets
ZHANG Wei, MA Wen-Lai, MA Zhi-Tao, PANG Bao-Jun
2006, 20(1): 1-5 .   doi: 10.11858/gywlxb.2006.01.001
Abstract(4537) PDF(155)
Ballistic Limit Analysis for Projectiles Impacting on Dual Wall Structures at Hypervelocity
DING Li, ZHANG Wei, PANG Bao-Jun, LI Can-An
2007, 21(3): 311-315 .   doi: 10.11858/gywlxb.2007.03.016
Abstract(4690) PDF(140)
Influence of Ultra High Pressure on Peroxidase Pectin Methyl Esterase and Soluble Protein in Litchi Fruit
HUANG Li, SUN Yuan-Ming, PAN Ke, CHEN Bai-Nuan, LIANG Di-Wen, CHEN Guo-Lian, YU Hong-Ying
2005, 19(2): 179-183 .   doi: 10.11858/gywlxb.2005.02.014
Abstract(4948) PDF(148)
Research on Dynamic Compressive Testing and Mechanical Properties of Silicon Rubber
ZHAO Xi-Jin, LU Fang-Yun, LIN Yu-Liang
2004, 18(4): 328-332 .   doi: 10.11858/gywlxb.2004.04.007
Abstract(4895) PDF(188)
New Method for Calculating Cold Energy, Cold Pressure and Cohesive Energy of Solids
RAN Xian-Wen, TANG Wen-Hui
2003, 17(1): 50-55 .   doi: 10.11858/gywlxb.2003.01.008
Abstract(5013) PDF(227)
The Behavior of Diaspore under High Pressure and High Temperature
LI Ming, LI Li-Xin, YANG Wu-Ming, ZHANG Pei-Feng, GAO Chun-Xiao, HE Chun-Yuan, HAO Ai-Min, LI Yan-Chun, LI Xiao-Dong, LIU Jing, et al
2008, 22(3): 333-336 .   doi: 10.11858/gywlxb.2008.03.020
Abstract(5063) PDF(166)
Pressure Effects on the Elastic Properties of the hcp Lithuim
CHEN Chang-Bo, CUI Tian, LIU Zhi-Ming, ZOU Guang-Tian, WEI Meng-Fu, CHEN Chang-An
2005, 19(4): 331-336 .   doi: 10.11858/gywlxb.2005.04.008
Abstract(4684) PDF(208)
Electrical Property and Phase Transition of CdSe under High Pressure
HE Chun-Yuan, GAO Chun-Xiao, LI Ming, HAO Ai-Min, HUANG Xiao-Wei, YU Cui-Ling, ZHANG Dong-Mei, WANG Yue, ZOU Guang-Tian
2008, 22(1): 39-42 .   doi: 10.11858/gywlxb.2008.01.009
Abstract(4573) PDF(148)
Initial Porosity Effect on the Shaped Charge Jet Behavior
LI Ru-Jiang, SHEN Zhao-Wu, WANG Feng-Ying
2008, 22(4): 445-448 .   doi: 10.11858/gywlxb.2008.04.019
Abstract(4768) PDF(160)
Constitutive Behaviors of a Silicone Rubber at High Strain Rates
LIN Yu-Liang, LU Fang-Yun, LU Li
2007, 21(3): 289-294 .   doi: 10.11858/gywlxb.2007.03.012
Abstract(4735) PDF(166)
Study on the Curves of Melting Temperature Pressure of Al, Cu and Pb
ZHENG Wei-Tao, ZHANG Rui-Lin
1993, 7(1): 42-46 .   doi: 10.11858/gywlxb.1993.01.006
Abstract(4766) PDF(197)
An Eulerian Adaptive Mesh Refinement Method for Three Dimensional Elastic-Plastic Hydrodynamic Simulations
LIU Jun, HE Chang-Jiang, LIANG Xian-Hong
2008, 22(1): 72-78 .   doi: 10.11858/gywlxb.2008.01.016
Abstract(4659) PDF(164)
Experimental Research on Glass Transition Temperature of Polymers in Compressed CO2
LI Zhi-Yi, MENG Ting-Yu, LIU Xue-Wu, WANG Yi, HU Da-Peng
2006, 20(3): 243-248 .   doi: 10.11858/gywlxb.2006.03.004
Abstract(4526) PDF(165)
Interface Treatment Method for Multi-Component Fluids Numerical Simulation
ZHANG Xue-Ying, ZHAO Ning, WANG Chun-Wu
2006, 20(3): 249-256 .   doi: 10.11858/gywlxb.2006.03.005
Abstract(4903) PDF(199)
Expressions of Cold Specific Energy and Cold Pressure for Detonation Products
LI Yin-Cheng
2005, 19(1): 71-79 .   doi: 10.11858/gywlxb.2005.01.013
Abstract(4551) PDF(147)
A Study on Square Plate Dynamic Response under Underwater Explosion
WU Cheng, JIN Yan, LI Hua-Xin
2003, 17(4): 275-282 .   doi: 10.11858/gywlxb.2003.04.006
Abstract(4617) PDF(167)
Modified Einstein Model to Consider Thermal Effect and Applied to Three Universal Equations of State
ZHANG Chao, SUN Jiu-Xun, TIAN Rong-Gang, LI Ming
2007, 21(3): 269-278 .   doi: 10.11858/gywlxb.2007.03.009
Abstract(4687) PDF(204)
Study on Penetration of Concrete Targets by Ogive-Nose Steel Projectile
ZHOU Ning, REN Hui-Qi, SHEN Zhao-Wu, HE Xiang, LIU Rui-Chao
2007, 21(3): 242-248 .   doi: 10.11858/gywlxb.2007.03.004
Abstract(4711) PDF(183)
Effect of High Pressure (HP) Treatments on Polyphenoloxidase (PPO) Activity in Pear Juices
ZENG Qing-Mei, PAN Jian, XIE Hui-Ming, YANG Yi, HUANG Xun-Duan
2004, 18(2): 144-148 .   doi: 10.11858/gywlxb.2004.02.009
Abstract(4694) PDF(203)
Synchrotron Radiation Diffraction of Gallium Oxide under High Pressure
CUI Qi-Liang, TU Bao-Zhao, PAN Yue-Wu, WANG Cheng-Xin, GAO Chun-Xiao, ZHANG Jian, LIU Jing, ZOU Guang-Tian
2002, 16(2): 81-84 .   doi: 10.11858/gywlxb.2002.02.001
Abstract(4868) PDF(235)
Pressure Calibration for the Sample Cell of YJ-3000t Multi-Anvil Press at High-Temperature and High-Pressure
SHAN Shuang-Ming, WANG Ri-Ping, GUO Jie, LI He-Ping
2007, 21(4): 367-372 .   doi: 10.11858/gywlxb.2007.04.006
Abstract(4803) PDF(222)
Study on the Intensity of the Cylindrical Vessel by the Inner Underwater Explosion Shock Wave
FAN Zi-Jian, SHEN Zhao-Wu, LIAO Xue-Yan, LIU Yuan-Dong
2008, 22(4): 402-408 .   doi: 10.11858/gywlxb.2008.04.011
Abstract(4800) PDF(160)
Multi-Shock Hugoniot Equation of State of Liquid Carbon Monoxide Measured By an Optical Analysis Technique
ZHENG Xue-Ping, LIU Fu-Sheng, ZHANG Ming-Jian, CHEN Xian-Meng, SUN Yue
2008, 22(4): 419-424 .   doi: 10.11858/gywlxb.2008.04.014
Abstract(4576) PDF(189)
Influence of Ultra High Pressure (UHP) on Micro-organisms in Watermelon Juice
ZENG Qing-Mei, PAN Jian, XIE Hui-Ming, YANG Yi, XU Hui-Qun
2004, 18(1): 70-74 .   doi: 10.11858/gywlxb.2004.01.012
Abstract(4636) PDF(157)
Instantaneous Void between Thermo-Baric Charge and Warhead Shell under Launching
ZHANG Qi, CUI Jun-Mei, JI Yan-Hua, WEI Ke-Zhen, DANG Hai-Yan, QIN Bin
2008, 22(1): 48-52 .   doi: 10.11858/gywlxb.2008.01.011
Abstract(4939) PDF(222)
Long-Time Correlation Effects and Fractal Braonian Motion
WANG Ke-Gang, LONG Qi-Wei
1991, 5(1): 52-56 .   doi: 10.11858/gywlxb.1991.01.008
Abstract(4811) PDF(183)
The Experimental and Theoretical Study on the Incident Pulse Shaping Technique
ZHAO Xi-Jin, LU Fang-Yun, WANG Wu, LI Ying-Hua, LIN Yu-Liang
2004, 18(3): 231-236 .   doi: 10.11858/gywlxb.2004.03.007
Abstract(4583) PDF(170)
Research on Piezoresistance Sensitivity of Yb Film Sensor
TENG Lin, YANG Bang-Chao, DU Xiao-Song, ZHOU Hong-Ren, CUI Hong-Ling, XIAO Qing-Guo
2004, 18(1): 90-93 .   doi: 10.11858/gywlxb.2004.01.016
Abstract(4577) PDF(151)
2D Numerical Simulation of Spallation in Three Steels with the Damage Function Model
PEI Xiao-Yang, LI Ping, DONG Yu-Bin
2007, 21(1): 71-76 .   doi: 10.11858/gywlxb.2007.01.012
Abstract(4465) PDF(149)
Mechanic Performances of Anti-Shoot Alumina Ceramic under Shock-Loading
DUAN Zhuo-Ping, GUAN Zhi-Yong, HUANG Feng-Lei
2003, 17(1): 29-34 .   doi: 10.11858/gywlxb.2003.01.005
Abstract(4834) PDF(359)
Effects of High Hydrostatic Pressure Treatment on Holothurians Autoenzyme Activity
XIA Yuan-Jing, LIU Zhi-Jun, LI Ning, CHEN Shu-Hua, DENG Ji-Song, LIU Xue-Wu, LI Zhi-Yi
2009, 23(5): 377-384 .   doi: 10.11858/gywlxb.2009.05.009
Abstract(4767) PDF(142)
A Numerical Analysis of the Influence of Buffer Material on Tantalum Flier Plate Velocity in the Hypervelocity Launcher
BAI Jing-Song, SHEN Qiang, TANG Mi, HU Jian-Bo, LUO Guo-Qiang, TAN Hua, ZHANG Lian-Meng
2008, 22(1): 19-24 .   doi: 10.11858/gywlxb.2008.01.005
Abstract(4808) PDF(171)
High Pressure Synthesis and Electric Transport Properties of La Filled CoSb3 Skutterudite Thermoelectric Materials
JIANG Yi-Ping, JIA Xiao-Peng, MA Hong-An, SU Tai-Chao, DONG Nan, DENG Le
2009, 23(2): 87-90 .   doi: 10.11858/gywlxb.2009.02.002
Abstract(5006) PDF(148)
First Principles Study of the Elastic, Electronic and Optical Properties of CdO under Pressure
HE Kai-Hua, ZHENG Guang, CHEN Gang, Lü Tao, WAN Miao, XIANG Dong, JI Guang-Fu
2007, 21(3): 299-304 .   doi: 10.11858/gywlxb.2007.03.014
Abstract(5032) PDF(176)
PbTe Syntheses by High-Pressure and High-Temperature Approach
ZHU Pin-Wen, JIA Xiao-Peng, CHEN Hai-Yong, CHEN Li-Xue, LI Dong-Mei, GUO Wei-Li, MA Hong-An, REN Guo-Zhong, ZOU Guang-Tian
2002, 16(3): 183-187 .   doi: 10.11858/gywlxb.2002.03.004
Abstract(4532) PDF(173)
An Improved of Experimental Hypervelocity Launcher and Simulation
BAI Jing-Song, TANG Mi, HUA Jing-Song, LI Ping, TAN Hua
2007, 21(3): 253-258 .   doi: 10.11858/gywlxb.2007.03.006
Abstract(4526) PDF(161)

Hosted by:Topical Communitte of High Pressure,
Chinese Physical Society

Sponsored by:Institute of Fluid Physics,CAEP

Editor-in-Chief:ZOU Guangtian