INDEX 



Reynolds, G. T., 260 



Rice, O. K., 127 



Richardson, J. M., 29, 102, 124, 417, 421 



Riemann equations, 25-28, 130-133 



Riemann function, 25, 38-40, 43 



rigid boundary, and bubble motion, 315- 



323; and shock waves, 51-53, 55-64, 



263-264 

 Road Research Laboratory, 250, 279, 



298, 341, 348, 368, 370, 384, 421 

 Rochelle salt, 161 



salinity, 268 



Savic, P., 183, 341 



scaling factors, for bubble motion, 291, 

 328, 335; for shock wave, see similarity 

 principle 



scattering of light, 212 



Schlieren photography, 223 



Schneider, W. G., 254, 387, 392 



schubenergie, see afterflow 



Scorah, R. L., 73 



Secchi disk, 213 



Seeger, R. J., 57, 60 



seismic waves, 264 



seismographic caps, 70 



Scitz, F., 151 



Shanes, A. M., 259 



Shapiro, M., 170, 190 



Shaw, R. A., 398 



Shiffman, M., 319, 362, 364 



shock tube, 181 



shock wave, 5-7, equations of motion for, 

 14-28; parameters of, 229-235; propa- 

 gation theories of, 114-139; tail of, 

 105, 228-231, 358; velocity of, 33-44, 

 218-220 



Silverman, D. M., 169 



similarity curves for shock waves, 235- 

 245 



similarity principle, for shock waves, 7, 

 110-114, 235-240; for bubble motion, 

 see scaling factors 



similarity restraint, 137 



Slichter, C. P., 392 



slick from shock wave, 210, 392 



Smith, P. F., 228 



Snell's law, for Hght, 220, 222; for pres- 

 sure waves, 268 



sound ranging, 349-352, 400-401 



sound waves, see acoustic waves 



speed effect, 151, 408 



spherical charges, 213-215 



Spitzer, R. W., 213, 224, 258 



spray dome, see dome of spray 



stabilized bubble position, see rest posi- 

 tion 



Stacey, D., 198 



Stanolind Development Laboratory, 169, 



179, 197 

 Stokes function, see stream function 

 strain rate, 151, 408 

 stream function, 314 

 surface phenomena, 11-12, 210-211, 392- 



399 

 surface reflection, of bubble pulse, 381- 



382; of shock wave, 53, 64, 261-264 

 surge impedance, 184 

 Swift, E., 213, 224 

 synchronization, 204-205, 217-218 



Tait equation, 38-39 



Taylor, G. I., 28, 45, 94, 278, 288, 292, 

 302, 355, 368, 378, 403 



Taylor Model Basin, 156, 160, 190, 197, 

 215, 227, 305, 346, 384 



telconax cable, 197 



Temperley, H. N. V., 341, 348 



tetryl, 69, 241-244 



termination of cables, see cables 



thickness of shock fronts, 45-47 



Thomas, L. H., 47 



Thomson, Sir J. J., 160 



three shock problem, 64 



time bases, 198, 204 



time constant of shock wave, definition 

 of, 230-231; observed values of, 6, 

 236-242; predicted values of, 123-126, 

 130, 132 



time spread of shock wave, 6-7, 119-123, 

 126, 266 



TNT, adiabatic expansion of products 

 of, 92-93; bubble period constant of, 

 282; bubble pulse parameters of, 387- 

 391; bubble scahng factors for, 297, 

 329; composition of, 67; decomposition 

 equations of, 88; detonation wave in, 

 94-100; shock wave parameters of, 

 240-242 



tourmaline, 161 



transient response, of amphfiers, 199- 

 203; of cables, 183-191; of mechanical 

 gauges, 149-150, 153; of piezoelectric 

 gauges, 164-169 



transmission by cables, 183-191 



transparency of water, 212-213 



turbulence, 377-379 



Underwater Explosive Research Labora- 

 tory (Woods Hole), 157, 161, 208. 224, 

 228, 384, 392, 430 



underwater photography, 211-218 



Undcx reports, 421, 430 



units of measurement, 234-235 



velocity, of bubble expansion, 226, 276- 

 278; of bubble migration, 297-299, 



