Author : Donald J. Shirley
Publisher :
Page : 52 pages
File Size : 30,51 MB
Release : 1977
Category :
ISBN :
During this reporting period, research was directed towards measuring sediment acoustic parameters in situ. Four field trips were made to use the ARL profilometer to make in situ sound speed measurements. Laboratory work continued to add the capability of measuring shear wave speed and acoustic impedance to the existing profilometer. Shear wave and compressional wave data measured in laboratory sediments are reported.
Author : Donald J. Shirley
Publisher :
Page : 98 pages
File Size : 17,98 MB
Release : 1978
Category : Marine sediments
ISBN :
During the period 1 January to 31 December, 1977, work under Contract N00014-76-C-0117 consisted of three parts: (1) in situ determination of compressional wave speed in ocean sediments using the ARL:UT profilometer; (2) development of transducers to measure shear wave and acoustic impedance parameters of sediments both in situ and in the laboratory; and (3) laboratory measurement of shear wave and compressional wave parameters of real and artificial sediments. Data obtained for the three parts of the program are reported.
Author : P. J. Vidmar
Publisher :
Page : 26 pages
File Size : 32,97 MB
Release : 1983
Category :
ISBN :
This report summarizes work done during the period 1 August 1975-30 June 1983. Major accomplishments include: Development and use of instrumentation to perform in situ measurements of acoustical parameters of marine sediments, measurement of shear and compressional wave parameters of laboratory sediments, development of theoretical descriptions of acoustic propagation in sediments, and laboratory experiments to test various theoretical models of propagation in sediments.
Author : Ronald C. Chaney
Publisher : ASTM International
Page : 561 pages
File Size : 41,15 MB
Release : 1985
Category : Technology & Engineering
ISBN : 9780803104310
Philadelphia, PA : ASTM, 1985.
Author : Donald J. Shirley
Publisher :
Page : 137 pages
File Size : 46,3 MB
Release : 1979
Category :
ISBN :
Work under Contract consisted of three parts: (1) redesign and updating of the ARL:UT profilometer system used to measure in situ sound velocities of ocean bottom sediments, (2) development of transducers to measure shear wave and acoustic impedance parameters of sediments, and (3) laboratory measurements to develop and confirm theoretical models for acoustic propagation in sediments. Data obtained for the three parts of the program are reported.
Author : Robert D. Stoll
Publisher : Springer
Page : 172 pages
File Size : 31,38 MB
Release : 1989-12-15
Category : Science
ISBN :
Sediment Acoustics describes the development of a mathematical model to be used to predict the propagation characteristics of acoustic waves in marine sediments. The model is based on the classical theory of Maurice Biot. Over the past 20 years, R.D. Stoll has published many technical papers covering various stages of development and different applications of Biot's theory. This work is summarized in one reference volume for the first time and presents enough introductory material so that researchers and students may use the model without extensive literature searches. Scientists working in the areas of acoustical oceanography, marine seismology, and ocean engineering will find this monograph useful in predicting the wave velocity and attenuation of seafloor sediments based on the geology of an area and such measurable physical properties as porosity and geostatic stress. A simple, interactive computer program is given as an aid in calculating velocity and attenuation, and a number of examples from recent field experiments are presented so that the predictions of the model may be compared with the "ground truth."
Author : Edwin Lee Hamilton
Publisher :
Page : 234 pages
File Size : 33,30 MB
Release : 1969
Category : Marine sediments
ISBN :
Author :
Publisher :
Page : 102 pages
File Size : 48,28 MB
Release : 1980
Category : Marine sediments
ISBN :
During the period 1 January - 31 December 1979, work under Contract N00014-76-C-0117 consisted of three parts: (1) use of the profilometer system to obtain in situ compressional wave data and to test in situ shear wave transducers, (2) development of theoretical models for acoustic propagation in sediments, and (3) laboratory measurements of compressional wave and shear wave parameters in laboratory sediments. Data obtained for the three parts of the program are reported. (Author).
Author : Theodore F. Argo
Publisher :
Page : 688 pages
File Size : 21,97 MB
Release : 2012
Category :
ISBN :
The propagation of acoustic waves through water-saturated granular sediments has been widely studied, yet existing propagation models can not adequately predict the speed and attenuation of sound across the range of frequencies of interest in underwater acoustics, especially in loosely packed sediments that have been recently disturbed by storms or wave action. Advances in modeling are currently dependent on experimental validation of various components of existing models. To begin to address these deficiencies, three well-controlled laboratory experiments were performed in gravity-settled glass beads and reconstituted sand sediments. Sound speed and attenuation measurements in the 0.5 kHz to 10 kHz range are scarce in the literature, so a resonator method was used to investigate a reconstituted sand sediment in this range. The literature contains laboratory and in situ measurements of sound speed and attenuation at higher frequencies, but existing models can not predict both the speed of sound and attenuation simultaneously in some sediments. A time-of-flight technique was used to determine the speed of sound and attenuation in monodisperse water-saturated glass beads, binary glass bead mixtures, and reconstituted sediment samples in the frequency range 200 kHz to 900 kHz to investigate the effect of sediment inhomogeneity. The effect of porosity, independent of changes in other sediment physical properties, has not been demonstrated in the experimental literature. Therefore, a fluidized bed technique was used to independently vary the porosity of monodisperse glass bead samples from 0.37 to 0.43 and a Fourier phase technique was used to determine the speed and attenuation of sound. Collecting these results together, measured sound speeds showed positive dispersion below 50 kHz while negative dispersion was observed above 200 kHz for some samples. Attenuation measurements showed an approximately f0̇5 dependence in the low frequency regime and an approximately f3̇5 dependence for large-grained samples in the high frequency regime. The laboratory experiments presented in this work demonstrate that both sound speed and attenuation in idealized loosely packed water-saturated sediments can not be simultaneously predicted by existing models within the uncertainties of the model input parameters, but the independent effect of porosity on sound speed can be predicted.
Author :
Publisher :
Page : 82 pages
File Size : 16,76 MB
Release : 1982
Category :
ISBN :
The work consisted of (1) final development of the ARL:UT profilometer recorder and transducer to enable the in situ measurement of compressional wave, shear wave, acoustic impedance, and static shear strength of ocean bottom sediments during geophysical coring, and (2) laboratory acoustical measurements on artificial sediments to test predictions of the Hovem model when the pore fluid viscosity is varied. The new profilometer recorder and transducer are described in detail as well as the microcomputer band playback system. Data obtained from the laboratory measurements are displayed.
