Measurement of Low-Frequency sound Attenuation in Marine Sediment
Yong-Min Jiang, and N. Ross Chapman

     Marine sediment compressional wave attenuation and its frequency dependence have been active topics in the ocean acoustics community. To support the predictions of the frequency dependence of the sediment attenuation, experimental studies are essential for providing the observations of the sediment attenuation as a function of frequency in different environments, such as sediment type, source-receiver range, water depth, etc. This paper proposes an experimental method for estimating marine sediment attenuation at low frequencies in shallow water. The experimental geometry is short range between a vertical line array and multiple source depths to cover bottom reflections over a wide span of grazing angles. Single bounce bottom-reflected (BR) and sub-bottom-reflected signals are used in the analysis to obtain the best approximation of the sediment intrinsic attenuation. The attenuation estimating method is demonstrated on chirp data (1.5-4.5 kHz) collected on the New Jersey Continental Shelf during the 2006 Shallow Water Experiment (2006). The data indicate a linear frequency dependence of the compressional wave attenuation for clay rich sediments on the outer shelf, and the estimated value is 0.15 dB/λ within the frequency band of 1.75-3.15 kHz. The observation of small sound-speed dispersion of ~15 m/s over the frequency band is consistent with a linear frequency dependence of attenuation.


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