Shock-ramp compression of tin near the melt line

Seagle, Christopher T.; Porwitzky, Andrew James

doi:10.1063/1.5044783

Title: Shock-ramp compression of tin near the melt line

Abstract

Tin has been shock compressed to ~69 GPa on the Hugoniot using Sandia’s Z Accelerator. A shockless compression wave closely followed the shock wave to ramp compress the shocked tin and probe a high temperature quasi-isentrope near the melt line. A new hybrid backwards integration – Lagrangian analysis routine was applied to the velocity waveforms to obtain the Lagrangian sound velocity of the tin as a function of particle velocity. Surprisingly, an elastic wave was observed on initial compression from the shock state. The presence of the elastic wave indicates tin possess a small but finite strength at this shock pressure, strongly indicating a (mostly) solid state. Finally, high fidelity shock Hugoniot measurements on tin sound velocities in this stress range may be required to refine the shock melting stress for pure tin.

Authors:

Seagle, Christopher T. ^[1]; Porwitzky, Andrew James ^[1]

Sandia National Lab. (SNL-NM), Albuquerque, NM (United States)

Publication Date:: Sun Jun 03 00:00:00 EDT 2018

Research Org.:: Sandia National Lab. (SNL-NM), Albuquerque, NM (United States)

Sponsoring Org.:: USDOE National Nuclear Security Administration (NNSA), Office of Defense Science (NA-113)

OSTI Identifier:: 1478333

Report Number(s):: SAND-2017-9994J
Journal ID: ISSN 0094-243X; 657036

Grant/Contract Number:: AC04-94AL85000

Resource Type:: Accepted Manuscript

Journal Name:: AIP Conference Proceedings

Additional Journal Information:: Journal Volume: 1979; Journal ID: ISSN 0094-243X

Publisher:: American Institute of Physics (AIP)

Country of Publication:: United States

Language:: English

Subject:: 36 MATERIALS SCIENCE

Citation Formats


                    Seagle, Christopher T., and Porwitzky, Andrew James. Shock-ramp compression of tin near the melt line.  United States: N. p., 2018. 
Web.  doi:10.1063/1.5044783.

Copy to clipboard


                    Seagle, Christopher T., & Porwitzky, Andrew James. Shock-ramp compression of tin near the melt line.  United States.  https://doi.org/10.1063/1.5044783

Copy to clipboard


                    Seagle, Christopher T., and Porwitzky, Andrew James. Sun .  
"Shock-ramp compression of tin near the melt line".  United States.  https://doi.org/10.1063/1.5044783.  https://www.osti.gov/servlets/purl/1478333.

Copy to clipboard


                    
@article{osti_1478333,

  title        = {Shock-ramp compression of tin near the melt line},

  author       = {Seagle, Christopher T. and Porwitzky, Andrew James},

  abstractNote = {Tin has been shock compressed to ~69 GPa on the Hugoniot using Sandia’s Z Accelerator. A shockless compression wave closely followed the shock wave to ramp compress the shocked tin and probe a high temperature quasi-isentrope near the melt line. A new hybrid backwards integration – Lagrangian analysis routine was applied to the velocity waveforms to obtain the Lagrangian sound velocity of the tin as a function of particle velocity. Surprisingly, an elastic wave was observed on initial compression from the shock state. The presence of the elastic wave indicates tin possess a small but finite strength at this shock pressure, strongly indicating a (mostly) solid state. Finally, high fidelity shock Hugoniot measurements on tin sound velocities in this stress range may be required to refine the shock melting stress for pure tin.},

  doi          = {10.1063/1.5044783},

  journal      = {AIP Conference Proceedings},

  number       = ,

  volume       = 1979,

  place        = {United States},

  year         = {Sun Jun 03 00:00:00 EDT 2018},

  month        = {Sun Jun 03 00:00:00 EDT 2018}

}

Copy to clipboard

Journal Article:

Free Publicly Available Full Text

Accepted Manuscript (DOE)

Publisher's Version of Record

https://doi.org/10.1063/1.5044783

Other availability

Search WorldCat to find libraries that may hold this journal

Citation Metrics:

Cited by: 4 works

Citation information provided by
Web of Science

Figures / Tables:

Figure 1: a) Cartoon of stripline shock-ramp hardware for the tin experiment. b) Measured true velocities of the tin-LiF interface for one of the sample pairs.

All figures and tables (2 total)

Save / Share:

Export Metadata

Save to My Library

Works referenced in this record:

Mechanical response of lithium fluoride under off-principal dynamic shock-ramp loading
journal, October 2016

Seagle, Christopher T.; Davis, Jean-Paul; Knudson, Marcus D.
Journal of Applied Physics, Vol. 120, Issue 16
DOI: 10.1063/1.4965990

Compressive strength measurements in aluminum for shock compression over the stress range of 4–22GPa
journal, August 2005

Huang, H.; Asay, J. R.
Journal of Applied Physics, Vol. 98, Issue 3
DOI: 10.1063/1.2001729

Laser interferometer for measuring high velocities of any reflecting surface
journal, November 1972

Barker, L. M.; Hollenbach, R. E.
Journal of Applied Physics, Vol. 43, Issue 11
DOI: 10.1063/1.1660986

A Multi-Phase Equation of State and Strength Model for Tin
conference, January 2006

Cox, G. A.
SHOCK COMPRESSION OF CONDENSED MATTER - 2005: Proceedings of the Conference of the American Physical Society Topical Group on Shock Compression of Condensed Matter, AIP Conference Proceedings
DOI: 10.1063/1.2263300

Mechanical and optical response of [100] lithium fluoride to multi-megabar dynamic pressures
journal, October 2016

Davis, Jean-Paul; Knudson, Marcus D.; Shulenburger, Luke
Journal of Applied Physics, Vol. 120, Issue 16
DOI: 10.1063/1.4965869

Magnetically driven isentropic compression experiments on the Z accelerator
journal, January 2001

Reisman, D. B.; Toor, A.; Cauble, R. C.
Journal of Applied Physics, Vol. 89, Issue 3, Article No. 1625
DOI: 10.1063/1.1337082

Successive phase transitions of tin under shock compression
journal, March 2008

Hu, Jianbo; Zhou, Xianming; Tan, Hua
Applied Physics Letters, Vol. 92, Issue 11
DOI: 10.1063/1.2898891

Shock-ramp compression: Ramp compression of shock-melted tin
journal, June 2013

Seagle, C. T.; Davis, J. -P.; Martin, M. R.
Applied Physics Letters, Vol. 102, Issue 24
DOI: 10.1063/1.4811745

Determining the refractive index of shocked [100] lithium fluoride to the limit of transmissibility
journal, July 2014

Rigg, P. A.; Knudson, M. D.; Scharff, R. J.
Journal of Applied Physics, Vol. 116, Issue 3
DOI: 10.1063/1.4890714

Characteristics analysis of Isentropic Compression Experiments (ICE)
journal, July 2006

Rothman, S. D.; Maw, J.
Journal de Physique IV (Proceedings), Vol. 134
DOI: 10.1051/jp4:2006134115

Equation of state and phase diagram of tin at high pressures
journal, July 2008

Khishchenko, K. V.
Journal of Physics: Conference Series, Vol. 121, Issue 2
DOI: 10.1088/1742-6596/121/2/022025

Measurement of the sound velocities behind the shock wave front in tin
journal, January 2012

Zhernokletov, M. V.; Kovalev, A. E.; Komissarov, V. V.
Combustion, Explosion, and Shock Waves, Vol. 48, Issue 1
DOI: 10.1134/S0010508212010145

Figures / Tables found in this record:

Figure 1 (p. 2)

Figure 2 (p. 4)

Figures/Tables have been extracted from DOE-funded journal article accepted manuscripts.

Similar Records in DOE PAGES and OSTI.GOV collections:

Equation of State Measurements on Iron Near the Melting Curve at Planetary Core Conditions by Shock and Ramp Compressions

Journal Article Grant, Sean Campbell ; Ao, Tommy ; Seagle, Christopher T. ; ... - Journal of Geophysical Research. Solid Earth

Abstract The outer core of the Earth is composed primarily of liquid iron, and the inner core boundary is governed by the intersection of the melt line and the geotherm. While there are many studies on the thermodynamic equation of state for solid iron, the equation of state of liquid iron is relatively unexplored. We use dynamic compression to diagnose the high‐pressure liquid equation of state of iron by utilizing the shock‐ramp capability at Sandia National Laboratories’ Z‐Machine. This technique enables measurements of material states off the Hugoniot by initially shocking samples and subsequently driving a further, shockless compression. Planetarymore »« less
https://doi.org/10.1029/2020jb020008

Full Text Available
Shock-ramp analysis test problem

Journal Article Rothman, S. D. ; Ali, S. J. ; Brown, J. L. ; ... - Journal of Applied Physics

Quasi-isentropic (ramp) compression is now a well-established experimental method and so are the analysis techniques to give Lagrangian sound speed, pressure, and density along the sample material's isentrope. A shock followed by ramp compression is a natural extension to investigate, for example, shock melt and refreeze on compression, or isentropes of states off the Hugoniot or principal isentrope. In practice, graded-density impactors produce initial shocks, compression by shaped laser pulses may be unable to produce a smooth pressure increase from zero, and incidental perturbations on the drive pulse may also give rise to shocks, so robust shock-ramp analysis methods willmore »« less
https://doi.org/10.1063/5.0045562

Full Text Available
Shock-compression and release behavior near melt states in aluminum. [Porous Al]

Journal Article Asay, J R ; Hayes, D B - J. Appl. Phys.; (United States)

The response of porous aluminum (rho/sub 0/ = 1.6 g/cm/sup 3/) when shock-compressed to states of partial melting and then released was investigated. There are no detectable changes in any of the Hugoniot properties in the region where melting should occur. However, release wave speeds in the completely compacted state of the porous aluminum specimens were found to depend critically upon the magnitude of the initial shock loading. For impact stresses below about 7 GPa, the measured release-wave velocity is well described by the assumption that the initial release is elastic. For initial impact stresses above 7 GPa, the speedmore »« less
https://doi.org/10.1063/1.321505
Sound velocities in shock-compressed soda lime glass: Melting and liquid-state response

Journal Article Renganathan, P. ; Duffy, T. S. ; Gupta, Y. M. - Physical Review B

Longitudinal sound velocities (and elastic moduli) were determined in soda lime glass (SLG) at peak shock stresses ranging between 40 and 90 GPa. Laser interferometry was used to obtain particle velocity histories and sound velocities by impacting SLG samples on lithium fluoride (LiF) optical windows. In all experiments, the SLG response consists of a sharp jump to a constant state followed by a release wave. The measured longitudinal sound velocities and moduli showed a marked decrease between 52 and 58 GPa, providing experimental evidence for the transformation from an amorphous solid to a liquid in shock-compressed SLG. Furthermore, the stressmore »« less
https://doi.org/10.1103/physrevb.104.014113

Full Text Available
Dynamic response of kovar to shock and ramp-wave compression.

Conference Sanchez, Dolores M ; Hall, Clint Allen ; Wise, Jack LeRoy ; ...

Complementary gas-gun and electro-magnetic pulse tests conducted in Sandia's Dynamic Integrated Compression Experimental (DICE) Facility have, respectively, probed the behavior of electronic-grade Kovar samples under controlled impact and intermediate-strain-rate ICE (Isentropic Compression Experiment) loading. In all tests, velocity interferometer (VISAR) diagnostics provided time-resolved measurements of sample response for conditions involving one-dimensional (i:e:, uniaxial strain) compression and release. Wave-profile data from the gas-gun impact experiments have been analyzed to assess the Hugoniot Elastic Limit (HEL), Hugoniot equation of state, spall strength, and high-pressure yield strength of shocked Kovar. The ICE wave-profile data have been interpreted to determine the locus of isentropicmore »« less

Similar Records

Title: Shock-ramp compression of tin near the melt line

Abstract

Citation Formats

Figures / Tables:

Mechanical response of lithium fluoride under off-principal dynamic shock-ramp loading journal, October 2016

Compressive strength measurements in aluminum for shock compression over the stress range of 4–22GPa journal, August 2005

Laser interferometer for measuring high velocities of any reflecting surface journal, November 1972

A Multi-Phase Equation of State and Strength Model for Tin conference, January 2006

Mechanical and optical response of [100] lithium fluoride to multi-megabar dynamic pressures journal, October 2016

Magnetically driven isentropic compression experiments on the Z accelerator journal, January 2001

Successive phase transitions of tin under shock compression journal, March 2008

Shock-ramp compression: Ramp compression of shock-melted tin journal, June 2013

Determining the refractive index of shocked [100] lithium fluoride to the limit of transmissibility journal, July 2014

Characteristics analysis of Isentropic Compression Experiments (ICE) journal, July 2006

Equation of state and phase diagram of tin at high pressures journal, July 2008

Measurement of the sound velocities behind the shock wave front in tin journal, January 2012

Mechanical response of lithium fluoride under off-principal dynamic shock-ramp loading
journal, October 2016

Compressive strength measurements in aluminum for shock compression over the stress range of 4–22GPa
journal, August 2005

Laser interferometer for measuring high velocities of any reflecting surface
journal, November 1972

A Multi-Phase Equation of State and Strength Model for Tin
conference, January 2006

Mechanical and optical response of [100] lithium fluoride to multi-megabar dynamic pressures
journal, October 2016

Magnetically driven isentropic compression experiments on the Z accelerator
journal, January 2001

Successive phase transitions of tin under shock compression
journal, March 2008

Shock-ramp compression: Ramp compression of shock-melted tin
journal, June 2013

Determining the refractive index of shocked [100] lithium fluoride to the limit of transmissibility
journal, July 2014

Characteristics analysis of Isentropic Compression Experiments (ICE)
journal, July 2006

Equation of state and phase diagram of tin at high pressures
journal, July 2008

Measurement of the sound velocities behind the shock wave front in tin
journal, January 2012