Acoustic fluidization: A new geologic process?

A number of geologic processes, particularly seismic faulting, impact crater slumping, and long runout landslides, require the failure of geologic materials under differential stresses much smaller than expected on the basis of conventional rock mechanics. This paper proposes that the low strengths apparent in these phenomena are due to a state of ‘acoustic fluidization’ induced by a transient strong acoustic wave field. The strain rates possible in such a field are evaluated, and it is shown that acoustically fluidized debris behaves as a newtonian fluid with a viscosity in the range 105–107 P for plausible conditions. Energy gains and losses in the acoustic field are discussed, and the mechanism is shown to be effective if internal dissipation in the field gives a Q ≳ 100. Whether such values for Q are realized is not known at present. However, acoustic fluidization provides a qualitatively correct description of the failure of rock debris under low differential stresses in the processes of faulting, crater slumping, and long runout landslides. Acoustic fluidization thus deserves serious consideration as a possible explanation of these phenomena.

[1]  B. Lucchitta Crater clusters and light mantle at the Apollo 17 site; A result of secondary impact from Tycho , 1977 .

[2]  R. Bagnold Experiments on a gravity-free dispersion of large solid spheres in a Newtonian fluid under shear , 1954, Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences.

[3]  J. Brune,et al.  Heat Flow, Stress, and Rate of Slip along the San Andreas Fault, , 1969 .

[4]  R. L. Shreve,et al.  The Blackhawk Landslide , 1968 .

[5]  D. L. Anderson,et al.  Theoretical Basis of Some Empirical Relations in Seismology by Hiroo Kanamori And , 1975 .

[6]  Hiroo Kanamori,et al.  Seismological aspects of the Guatemala Earthquake of February 4, 1976 , 1978 .

[7]  H. Deresiewicz,et al.  Mechanics of Granular Matter , 1958 .

[8]  M. McSaveney Chapter 6 - Sherman Glacier Rock Avalanche, Alaska, U.S.A. , 1978 .

[9]  W. McKinnon An investigation into the role of plastic failure in crater modification , 1978 .

[10]  M. A. Chinnery The strength of the Earth's crust under horizontal shear stress , 1964 .

[11]  K. Howard Avalanche Mode of Motion: Implications from Lunar Examples , 1973, Science.

[12]  M. Nafi Toksöz,et al.  Structure of the Moon , 1974 .

[13]  B. Lucchitta Landslides in the Valles Marineris, Mars. , 1979 .

[14]  J. Brune Tectonic stress and the spectra of seismic shear waves from earthquakes , 1970 .

[15]  R G McConnell,et al.  Report on the great landslide at Frank, Alta., 1903 , 1904 .

[16]  R. Bagnold,et al.  The flow of cohesionless grains in fluids , 1956, Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences.

[17]  Jean Goguel,et al.  Scale-Dependent Rockslide Mechanisms, with Emphasis on the Role of Pore Fluid Vaporization , 1978 .

[18]  B. Lucchitta A large landslide on Mars , 1978 .

[19]  Kenneth J. Hsü,et al.  Catastrophic Debris Streams (Sturzstroms) Generated by Rockfalls , 1975 .

[20]  K. Hsü Chapter 1 - Albert Heim: Observations on Landslides and Relevance to Modern Interpretations , 1978 .

[21]  R. Scott Viscous flow of craters , 1967 .

[22]  Baxter H. Armstrong,et al.  Acoustic emission prior to rockbursts and earthquakes , 1969 .

[23]  J. Dieterich Earthquake Mechanisms and Modeling , 1974 .