Microwave diagnostics of shock-wave and detonation processes

L. I. Mandel’shtam and N. D. Papaleksi (eds.), Current Studies of Radio-Wave Propagation along the Earth’s Surface (collected scientific papers) [in Russian], Moscow-Leningrad (1945). B. Koch, Physics of Fast Processes, Ed. by N. A. Zlatin [Russian translation], Vol. 1, Mir, Moscow (1971). G. H. McCall, W. L. Bongianni, and G. A. Miranda, “Microwave interferometer for shock wave, detonation and material motion measurements,” Rev. Sci. Instrum., 56, No. 8, 1612–1618 (1985). B. R. Levin, Theoretical Foundations of Statistical Radio Engineering [in Russian], Sov. Radio, Moscow (1966), Book 1. V. E. Zarko, D. V. Vdovin, and V. V. Perov, “Methodical problems of solid-propellant burning-rate measurements using microwaves,” Combust., Expl., Shock Waves, 36, No. 1, 62–71 (2000). M. Hermann, W. Engel, and N. Eisenreich, “Termal expansion, transitions, sensitivities and burning velocitys of HMX,” Propellants, Explosives, Pyrotechnics, 17, 190–195 (1992). A. D. Krall, B. C. Glancy, and H. W. Sandusky, “Microwave interferometry of shock waves. 1. Unreacting porous media,” J. Appl. Phys., 74, No. 10, 6322–6327 (1993). A. V. Rodionov, V. A. Kanakov, and S. Yu. Lupov, “Methods of processing the results of radio interferometric measurements of gas-dynamic parameters,” in: Extreme States of Matter. Detonation. Shock Waves, Int. Conf. VII Kharitonov Topical Scientific Readings, RFNC-VNIIEF, Sarov (2005), pp. 680–685. G. Luther, L. Veeser, and B. Warthen, “A microwave interferometer to measure particle and shock velocities simultaneously,” in: S. C. Schmidt, R. D. Dick, J. W. Forbs, and D. G. Tasker (eds.), Shock Compression of Condensed Matter-1991 (Williamsburg, Virginia, June 17–20, 1991), Elsevier (1992), pp. 775–778. V. A. Kanakov, S. Yu. Lupov, V. V. Parkhachev, and A. V. Rodionov, “Multimode radio interferometry as a means of increasing the number of measured parameters of explosives,” in: Extreme States of Matter. Detonation. Shock Waves, Int. Conf. VII Kharitonov Topical Scientific Readings, RFNC-VNIIEF, Sarov (2007), pp. 665–670. R. K. Khanna and S. K. Upadhyay, “Free space reflection type interferometric method for dielectric studies of sheet materials,” Indian J. Phys, 74B, No. 4, 281–286 (2000). Zhihong Ma and Seichi Okamura, “Permittivity determination using amplitudes of transmittion and reflection coefficients at microwave frequency,” IEEE Trans. Microwave Theory Tech., 47, No. 5, 546–550 (1999). R. F. Trunin (ed.), Experimental Data on the Shock-Wave Compression and Adiabatic Expansion of Condensed Materials [in Russian] RFNC-VNIIEF, Sarov (2006). B. I. Sazhin (ed.), Electric Properties of Polymers [in Russian], Khimiya, Leningrad (1986). A. V. Rodionov, V. M. Bel’skii, E. N. Bogdanov, et al., “Determination of the depth of initiation of detonation radio wave method of plastic-bonded HMX and TATB,” in: Extreme States of Matter. Detonation. Shock Waves, Int. Conf. VII Kharitonov Topical Scientific Readings, RFNC-VNIIEF, Sarov (2009), pp. 69–73. M. F. Foltz, “Pressure dependence of the reaction rate of TATB at high pressure,” Propellants, Explosives, Pyrotechnics, 18, 210–216 (1993). E. N. Bogdanov, V. M. Bel’skii, and A. V. Rodionov, “The effect of shock-compressed air in front of an accelerated plate on radio interferometry measurements of velocity,” in: Extreme States of Matter. Detonation. Shock Waves, Int. Conf. VII Kharitonov Topical Scientific Readings, RFNC-VNIIEF, Sarov (2007), pp. 680–686.