Measurement of shock and re-shock Hugoniot data of liquid nitrogen

IF 1.2 4区 物理与天体物理 Q3 PHYSICS, MULTIDISCIPLINARY
Muhammad Sabeeh Akram, Shumail Sattar, Zhuo-Ning Fan, Qi-jun Liu, Fu-sheng Liu
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引用次数: 1

Abstract

ABSTRACT In this work, the equation-of-state data for liquid nitrogen shock compressed to 43 GPa along the principal Hugoniot and reflected-shock data up to 91 GPa were reported. A cryogenic target was used to liquefy the gas that was then further compressed by high-speed impactors. The first- and second-shock states were observed by a high-precision Doppler pin system (DPS). Optical wavefrom of DPS resulted in the first-shock velocity from which other derivative quantities i.e. particle-velocity, specific-volume, internal-energy, and Grüneisen-parameter, were determined. Our results and published equation-of-state data were used to extrapolate the principal Hugoniot. Their comparison showed softening above 27 GPa, attributed to the absorption of thermal energy that dissociates the molecular nitrogen. Our single-shock data provided a good match to available Hugoniot data. The reduced velocity profiles allowed us to detect optical reflectance of the dissociated liquid phase, and the apparent shock-velocity was used to determine the true shock-velocity in dissociation threshold.
液氮的冲击和再冲击Hugoniot数据的测量
摘要在这项工作中,液氮冲击压缩到43的状态方程数据 主Hugoniot沿线的GPa和高达91的反射冲击数据 报告了GPa。低温靶被用来液化气体,然后由高速冲击器进一步压缩。利用高精度多普勒钉系统(DPS)观测了第一和第二激波状态。DPS的光波产生了第一冲击速度,由此确定了其他导数,即粒子速度、比体积、内能和Grüneisen参数。我们的结果和已发表的状态方程数据被用来推断主要的Hugoniot。他们的比较显示软化超过27 GPa,归因于对热能的吸收,使分子氮离解。我们的单次冲击数据与Hugoniot的可用数据非常匹配。降低的速度剖面使我们能够检测离解液相的光学反射率,表观冲击速度用于确定离解阈值中的真实冲击速度。
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来源期刊
High Pressure Research
High Pressure Research 物理-物理:综合
CiteScore
3.80
自引率
5.00%
发文量
15
审稿时长
2 months
期刊介绍: High Pressure Research is the leading journal for research in high pressure science and technology. The journal publishes original full-length papers and short research reports of new developments, as well as timely review articles. It provides an important forum for the presentation of experimental and theoretical advances in high pressure science in subjects such as: condensed matter physics and chemistry geophysics and planetary physics synthesis of new materials chemical kinetics under high pressure industrial applications shockwaves in condensed matter instrumentation and techniques the application of pressure to food / biomaterials Theoretical papers of exceptionally high quality are also accepted.
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