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References
Abegg F. and Anderson A. L., The acoustic turbid layer in muddy sediments of Eckernfoerde Bay, Western Baltic: methane concentration, saturation and bubble characteristics. Mar. Geol. 137, 137-147 (1997).
Anderson A. L. , Abegg F., Hawkins J. A., Duncan M. E. and Lyons A. P., Bubble populations and acoustic interaction with the gassy floor of Eckernforde Bay. Continental Shelf Research 18, 1807-1838 (1998).
Hovem J. M., The nonlinearity parameter of saturated marine sediments. J. Acoust. Soc. Am. 66,1463-1467 (1979).
Stefanon A., Marine sedimentology through modern acoustical methods: UNIBOOM. Boll. Oceanol. Teor. Appl. II(6), 113-144 (1985).
Turgut A. and Yamamoto T., Measurements of acoustic wave velocities and attenuation in marine sediments. J. Acoust. Soc. Am. 87, 2376-2383 (1990).
Zabolotskaya E. A. and Soluyan S. I., Emission of harmonic and combination-frequency waves by air bubbles. Sov. Phys. Acoust. 18, 396-398 (1972).
Lyons A. P., Duncan M. E., Anderson A. L. and Hawkins J. A., Predictions of the acoustic scattering response of free methane bubbles in muddy sediments. J. Acoust. Soc. Am. 99, 163-172 (1996).
Boudreau B. P., Gardiner B. S. and Johnson B. D., Rate of growth of isolated bubbles in sediments with a distributed diagenetic source of methane. Limnol. Oceanogr. 46, 616-622 (2001).
Anderson A. L. and Hampton L. D., Acoustics of gasbearing sediments I. Background. J. Acoust. Soc. Am. 67, 1865-1889 (1980).
Anderson A. L. and Hampton L. D., Acoustics of gasbearing sediments II. Measurements and Models. J. Acoust. Soc. Am. 67, 1890-1903 (1980).
Minnaert M., On musical air bubbles and the sounds of running water. Philos. Mag. 10(235) (1933).
Karl S. G., Williams K. L. and Lim R., Double monopole resonance of a gasfilled, spherical cavity in a sediment. J. Acoust. Soc. Am. 103, (1998).
Geological Map of the Baltic Sea Bottom, Gulf of Gdańsk sheet, Polish Geological Institute, Warsaw (1992).
Clay C. S. and Medwin H., Acoustical Oceanography, Wiley Interscience Publication (1977).
Boyle F. A. and Chotiros N. P., Nonlinear acoustic scattering from a gassy poroelastic seabed. J. Acoust. Soc. Am. 103(3), 1328-1336 (1998).
Jakacki J., Application of nonlinear acoustical phenomena in investigations of gas bubbles in sea (in Polish). Ph.D. Thesis, Institute of Oceanology of Polish Academy of Sciences, Sopot (2002).
Jakacki J., Klusek Z. and Tegowski J., The nonlinear method of gas bubbles detection in the bottom sediments, Revista de Acústucam XXXIII 2002 (CD, ISBN: 8487985068).
Tegowski J., Characteristics of backscattered ultrasonic signals from the floor of the southern Baltic (in Polish). Ph.D. Thesis, Institute of Oceanology of Polish Academy of Sciences, Sopot (1994).
Pieczka F., Geomorfologia I Osady Denne Basenu Gańskiego Peribalticum Problemy Badawcze Obszaru Bałtyckiego, Ossolineum Gdańsk, 79118, (1980) (in Polish).
Tęgowski J., Jakacki J., Klusek Z. and Rudowski S., Nonlinear Acoustical Methods in the Detection of Gassy Sediments in the Gulf of Gdansk, HYDROACOUSTICS 6, 151–158 (2003).
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Tegowski, J., Klusek, Z., Jakacki, J. (2006). Nonlinear acoustical methods in the detection of gassy sediments. In: Caiti, A., Chapman, N.R., Hermand, JP., Jesus, S.M. (eds) Acoustic Sensing Techniques for the Shallow Water Environment. Springer, Dordrecht. https://doi.org/10.1007/978-1-4020-4386-4_10
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