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References
In-Material and Rear-Surface Gauges
Barbee, T.W., “Some Aspects of Dislocation Dynamics in Metals”, Stanford University, ONR-SU Report No. 65–33, 1965 (D635023).
Bauer, F., “Properties and Shock Loading Response of Poled Ferroelectric PVF2 polymer gauges,” The 1987 ASME Applied Mechanics, Bioengineering, and Fluids Engineering Conference. Cincinnati, Ohio, June 14–17, (1987).
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Charest, J.A., “Development of a Carbon Shock Pressure Gauge,” Defense Nuclear Agency (U.S.) report TR DNA 3101 F, (1973).
Charest, J.A. and C.S. Lynch, “The Response of PVF2 Stress Gauges to Shock Wave Loading.” in: Shock Compression of Condensed Matter — 1989 (eds. S.C. Schmidt, J.N. Johnson, and L.W. Davison) North-Holland, Amsterdam, pp. 797–800, (1990).
Charest, J.A. and C.S. Lynch, “A Simple Approach to Piezofilm Stress Gauges.” in: Shock Compression of Condensed Matter — 1991 (eds. S.C. Schmidt, R.D. Dick, J.W. Forbes, and D.G. Tasker), Elsevier, Amsterdam, pp. 897, (1992).
Charest, J.A. and C.S. Lynch, “Practical Considerations of the Piezofilm Stress Gauge Technique,” 41st ARA meeting, San Diego CA, (1990).
Charest, J.A. and C.S. Lynch, “Effects of Lateral Strains on PVF2 Stress Gauges,” 42nd ARA meeting, Adelaide, Australia, (1991).
Charest, J.A. and M.D. Lilly, “PVF2 Stress Gauges for Non-Planar Wave Applications, Part I,” in: High-Pressure Science and Technology — 1993 (eds. S.C. Schmidt, J.W. Shaner, G.A. Samara, and M. Ross) American Institute of Physics, New York, pp. 1731–1734, (1994).
Charest, J.A. and M.D. Lilly, “Effects of Large Strains on PVDF Gauges,” 46th ARA meeting, St Louis France, (1996).
Chen D.Y., Y.M. Gupta and M.H. Miles. “Quasi-Static Experiments to Determine Material Constants for the Piezoresistance Foils Used in Shock Wave Experiments,” J. Appl. Phys. 55(1), pp. 3984, (1984).
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Lynch, C.S., “Strain Compensated Thin Film Stress Gauges for Stress Wave Measurements in the Presence of Lateral Strains,” Rev. of Sci. Inst. 66(12), pp. 5582–5589, (1995).
Rosenberg, Z., Y. Partom, and D. Yaziv, “The Response of Manganin Gauges Shock Loaded in the 2-D Straining Mode,” J. Appl. Phys. 52(2), pp. 4610, (1981).
Interferometry
Amory, B.T., “Wide Range Velocity Interferometer”, in: Proc. Sixth Symp. (International) on Detonation, Report ACR-221, Office of Naval Research, Arlington, VA, pp. 673–681, (1976).
Barker L.M., and R.E. Hollenbach, “Laser Interferometer for Measuring High Velocities of Any Reflecting Surface”, J. Appl. Phys. 43(11), p. 4669, (1972).
Barker, L.M., “The New Valyn Multi-Beam VISARs,” Proceedings, 49th Meeting of the Aeroballistic Range Association, (1998).
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Hemsing, W.F., “Velocity Sensing Interferometer (VISAR) Modification,” Rev. Sci. Instr. 50(1), pp. 73, (1979).
Isbell, W.M., “A Simplified, Compact VISAR: Concept and Construction,” Proceedings, 42nd Meeting of the Aeroballistic Range Association, (1991).
Isbell, W.M., “An Infrared VISAR for Remote Measurement of Projectile Motion,” Proceedings, 39th Meeting of the Aeroballistic Range Association, (1988).
Isbell, W.M., “Extending the Range of the Third-Generation VISAR from 30 m/s to 30,000 m/s,” Proceedings, 47th Meeting of the Aeroballistic Range Association, (1996).
Prins, W.C., R.J. van Esveld, L.K. Cheng, H.J. Verbeek, and A.C. v.d. Steen, “Measurements of Shock Wave Properties with Fabry-Perot Interferometer,” Proceedings, 49th Meeting of the Aeroballistic Range Association, (1998).
Sweatt, W.C., P.L. Stanton, and O.B. Crump, Jr., “Simplified VISAR System,” Sandia National Laboratories report SAND90-2419C, and Society of Photographic Instr. and Engng. Vol. 1346, (1990).
Yoshida, K., National Institute for Material and Chemical Research, Tsukuba, Japan, private communication, (1995).
Recommended Reading on Additional Interferometric Methods
Asay, J.R., (1975) “Shock and Release Behavior in Porous 1100 Aluminum”, J. Appl. Phys. 46.
Barker, L.M., and R.E. Hollenbach. Rev. Sc. Instr. 36, 4208 (1965).
Christman, D.R., W.M. Isbell, and S.G. Babcock,“Measurements of Dynamic Properties of Materials, Vol. V: OFHC Copper”, General Motors Materials and Structures Laboratory, report DASA-2501, July 1971 (AD728846) (1970).
Clifton, R.J. “Analysis of the Laser Velocity Interferometer.” J. Appl. Phys 41, p. 3535 (1970).
Erskine, D.J. and N.C. Holmes, “Imaging White Light VISAR”, 22nd International Congress on High Speed Photonics and Photography, Santa Fe, New Mexico, (1996).
Froeschner, K.E., et al, “Subnanosecond Velocimetry with a New Kind of VISAR,” 22nd International Congress on High Speed Photonics and Photography, Santa Fe, New Mexico (1996).
Gidon, S. and G. Behar, “Multiple-Line Laser Doppler Velocimetry”, Appl. Optics 27, pp. 2315–2319, (1988).
Gillard, C.W., G.S. Ishikawa, J.F. Peterson, J.L. Rapier, J.C. Stover, and N.L. Thomas, Lockheed Report No. N-25-67-1, (unpublished) (1968).
Gooseman, D.R., J. Appl. Phys. 45, p. 3516, (1975).
Hemsing, W.F., A.R. Mathews, R.H. Warnes, M.J. George and G.R Whittemore, “VISAR: Line-Imaging Interferometer”, American Physical Society Topical Conference, Williamsburg, VA, June 17–21 (1991).
Isbell, W.M., “The Versatile VISAR: An Interferometer for Shock Wave and Gas Gun Diagnostics”, Proceedings, 26th Annual Meeting of the Aeroballistic Range Association, (1976).
Isbell, W.M., and P.W.W. Fuller, “Wide Range, High Resolution Measurements of Projectile Motion Using Laser Interferometry,” 27th Annual Meeting, SPIE and High Speed Photonics and Videography Conference, TR-16-83, (1983).
Isbell, W.M., “Laser Interferometry for Accurate Measurements of Projectile Motion”, Proceedings, 34th Meeting of the Aeroballistic Range Association (1983).
Isbell, W.M., “Initial Tests of VISAR Interferometry to Measure E.M. Launcher Projectile Motion”, Proceedings, 38th Meeting of the Aeroballistic Range Association, (1987).
Isbell, W.M., “Interferometric In-Bore Velocity Measurements of Electromagnetically-Launched Projectiles”, Proceedings, 41st Meeting of the Aeroballistic Range Association, (1990).
Isbell, W.M., and J.R. Christman, “Shock Propagation and Fracture in 6061-T6 Aluminum from Wave Profile Measurements”, General Motors Materials and Structures Laboratory, report DASA-2419, (AD705536), (1970).
Isbell, W.M., Measurements of the Dynamic Response of Materials to Impact Loading, Doctoral Thesis, Shock Wave Research Center, Tohoku University, Sendai, Japan (1993).
Isbell, W.M., “A Combined Displacement/Velocity Interferometer for Impact Measurements at 0.1 to 100 m/s”, Proceedings, 32nd Meeting of the Aeroballistic Range Association, (1981).
Isbell, W.M., “An Infrared VISAR for Remote Measurement of Projectile Motion”, Proceedings, 39th Meeting of the Aeroballistic Range Association, (1988).
Isbell, W.M., “Extending the Range of the Third-Generation VISAR from 30 m/s to 30,000 m/s,” Proceedings, 47th Meeting of the Aeroballistic Range Association, (1996).
Isbell, W.M., “Modern Instrumentation for Measurements of Shock Waves in Solids”, Proceedings, Japanese Shock Wave Symposium, Tokyo, Japan, (1999).
Johnson, J.N., and L.M. Barker, “Dislocation Dynamics and Steady Plastic Wave Profiles in 6061-T6 Aluminum.” J. Appl. Phys. 40, pp. 4321–4334, (1969).
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Yoshida, K., National Institute for Material and Chemical Research for Material and Chemical Research, Tsukuba Japan, private communication, (1996).
Recommended Reading on other Time-Resolved Diagnostics
Chhabildas, L.C., and R. A. Graham, in Techniques and theory of stress measurements for shock wave applications, ed. By R. R. Stout, E. R. Norwood, and M. E. Fourney, Amer. Soc. of Mech. Eng. NY, AMD 83, 1–18 (1987).
d'Almeida, T. and Y.M. Gupta, “X-ray Diffraction Measurements in KCl Shocked Along [100],” in: Shock Compression of Condensed Matter — 1999 (eds. M.D. Furnish, L.C. Chhabildas, and R.S. Hixson) American Institute of Physics, New York, (2000).
Graham, R. A., and J. R. Asay, “Measurements of wave profiles in shock-loaded solids” High-Temperatures-High Pressures 10, 355–390 (1978).
Gruzdkov, C.S. and Y.M. Gupta, “Optical Measurements to Probe Inelastic Deformation in Shocked, Brittle Materials,” in: Shock Compression of Condensed Matter—1999 (eds. M.D. Furnish, L.C. Chhabildas, and R.S. Hixson) American Institute of Physics, New York, (2000).
Gustavsen, R. and Y.M. Gupta, “Time-Resolved Spectroscopic Reflection Measurements in Shock-Loaded Materials,” J. Appl. Phys. 69, p. 918, (1991).
Horn, P.D., and Y.M. Gupta, “Wavelength Shift of the Ruby Luminescence R lines under Shock Compression,” Appl. Phys. Lett. 49, p. 856, (1986).
Knudson, M.D., and Y.M. Gupta, Stimulated Emission to Measure R Shifts in Shocked Ruby,” J. Appl. Phys. 85, p. 6425, (1999).
Knudson, M.D., “Picosecond Time Resolved Electronic Spectroscopy in Shock,” Rev. Sci. Inst. 70, p. 1743, (1999).
Kwiatkowski, C.S., and Y.M. Gupta, “Optical Measurements to Probe Inelastic Deformation,” in: Shock Compression of Condensed Matter—1999 (eds. M.D. Furnish, L.C. Chhabildas, and R.S. Hixson) American Institute of Physics, New York, p. 641, (2000).
Rigg, P. and Y.M. Gupta, X-ray Diffraction, in: Shock Compression of Condensed Matter — 1999 (eds. M.D. Furnish, L.C. Chhabildas, and R.S. Hixson) American Institute of Physics, New York, p. 1051, (2000).
Winey, J.M. and Y.M. Gupta, “Raman Spectroscopy,” J. Phys. Chem. B 101, p. 10733, (1997).
d'Almeida, T. and Y.M. Gupta, “X-ray Diffraction Measurements in KCl Shocked Along [100],” in: Shock Compression of Condensed Matter — 1999 (eds. M.D. Furnish, L.C. Chhabildas, and R.S. Hixson) American Institute of Physics, New York, (2000).
Yuan, G., R. Fong, and Y.M. Gupta., “Compression and Shear Wave Measurements to Characterize the Shocked State in Silicon Carbide,” J. Appl. Phys. 89, p. 5372, (2001).
Gruzdkov, C.S. and Y.M. Gupta, “Optical Measurements to Probe Inelastic Deformation in Shocked, Brittle Materials,” in: Shock Compression of Condensed Matter — 1999 (eds. M.D. Furnish, L.C. Chhabildas, and R.S. Hixson) American Institute of Physics, New York, (2000).
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Isbell, W.M. (2005). Time-Resolved Gauges for Measurements of Shock Waves in Solids. In: Chhabildas, L.C., Davison, L., Horie, Y. (eds) High-Pressure Shock Compression of Solids VIII. High-Pressure Shock Compression of Condensed Matter. Springer, Berlin, Heidelberg. https://doi.org/10.1007/3-540-27168-6_9
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