pure and applied geophysics

, Volume 147, Issue 2, pp 289–304 | Cite as

Rock-mass characterization using intrinsic and scattering attenuation estimates at frequencies from 400 to 1600 Hz

  • Andrew J. Feustel
  • Cezar-Ioan Trifu
  • Theodore I. Urbancic
Article
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Abstract

Intrinsic and scatteringS-wave quality factors (Qβ) were estimated using the Multiple Lapse Time Window Analysis (MLTWA) for microseismic events (M<−1) with source-sensor distances of 45 to 120 m, associated with an excavation at 630 m depth in Strathcona Mine, Sudbury, Canada. Additional information on the rock mass was provided by underground structural mapping data. IntrinsicQβ values, at 800 Hz, were on the order of 140, similar to quality factor values obtained in previous studies using Spectral Decay and Coda-Q methods (120 to 170). The scattering quality factor at this frequency was about 520. An observed frequency dependence of the scattering attenuation suggested that a decrease in the density of scatterers, with scale lengths on the order of 2 m, exists at the site. Characteristic fracture scale lengths were considered to range from 4 to 6 m as identified in the mapping data. These observations were supported by the increase in scattering found for seismic waves with frequencies less than 1000 Hz. By assuming that the identified scatters are characteristic faults, these scatterers can then be considered to increase nonsimilar behavior in source scaling. Overall, our results suggest that MLTWA provides a practical method for remotely characterizing the quality of a rock mass when visual observations are not attainable.

Key words

Intrinsic and scattering attenuation multiple lapse time window analysis characteristic fracture scale lengths seismic source scaling 
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Copyright information

© Birkhäuser Verlag 1996

Authors and Affiliations

  • Andrew J. Feustel
    • 1
  • Cezar-Ioan Trifu
    • 2
  • Theodore I. Urbancic
    • 2
  1. 1.Department of Geological SciencesQueen's UniversityKingstonCanada
  2. 2.Engineering Seismology Group CanadaKingstonCanada

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