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Your search keyword '"Dai, C. -D."' showing total 8 results
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8 results on '"Dai, C. -D."'

1. Evidence for mechanical softening-hardening dual anomaly in transition metals from shock compressed vanadium

Author

Wang, Hao, Li, J., Zhou, X. M., Tan, Y., Hao, L., Yu, Y. Y., Dai, C. D., Jin, K., Wu, Q., Jing, Q. M., Chen, X. R., Yan, X. Z., Wang, Y. X., and Geng, Hua Y.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter, Physics - Applied Physics, Physics - Computational Physics
Abstract

Solid usually becomes harder and tougher under compression, and turns softer at elevated temperature. Recently, compression-induced softening and heating-induced hardening (CISHIH) dual anomaly was predicted in group VB elements such as vanadium. Here, the evidence for this counterintuitive phenomenon is reported. By using accurate high-temperature high-pressure sound velocities measured at Hugoniot states generated by shock-waves, together with first-principles calculations, we observe not only the prominent compression-induced sound velocity reduction, but also strong heating-induced sound velocity enhancement, in shocked vanadium. The former corresponds to the softening in shear modulus by compression, whereas the latter reflects the reverse hardening by heat. These experiments also unveil another anomaly in Young's modulus that wasn't reported before. Based on the experimental and theoretical data, we infer that vanadium might transition from BCC into two different rhombohedral (RH1 and RH2) phases at about 79GPa and 116GPa along the Hugoniot, respectively, which implies a dramatic difference in static and dynamic loading, as well as the significance of deviatoric stress and rate-relevant effects in high-pressure phase transition dynamics., Comment: 43 pages, 16 figures, with Supplementary Material

Published
2022
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4. Dynamic densification behavior of nanoiron powders under shock compression.

Author

Dai, C. D., Eakins, D. E., and Thadhani, N. N.

Subjects
*BULK solids, *THICKNESS measurement, *CRYSTALS, *MEASURING instruments, *POROUS materials, *GRANULAR materials
Abstract

The dynamic densification behavior of nanoiron powder (∼25 nm particle size) prepressed to ∼35% and ∼45% of solid density was determined based on measurements of shock input stress and wave velocity by using piezoelectric stress gauges. The experimentally determined shock densification response is observed to be sensitive to the initial density (or porosity) of prepressed nanoiron powder compacts. Hugoniot measurements show an obvious densification-distension transition at ∼2 GPa for the ∼35% dense and ∼6 GPa for the ∼45% dense powder compacts. The densification and shock compression responses of the nanoiron powders are also calculated by using isobaric and isochoric models. Correlations of the model calculations with the measured data indicate that the shock Hugoniot of nanoiron powders cannot be correctly described by the currently available analytical models that are otherwise capable of predicting the Hugoniot of highly porous materials (prepressed compacts) of micron-sized powders. [ABSTRACT FROM AUTHOR]

Published
2008
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