Geotechnical characterisation of stratocone crater wall sequences, White Island Volcano, New Zealand

Geotechnical characterisation is undertaken for 3 broad units comprising the bulk of the stratigraphy identified on White Island Volcano, Bay of Plenty, New Zealand, an active island stratovolcano. Field and laboratory measurements were used to describe rock mass characteristics for jointed lava flow units, and ring shear tests were undertaken to derive residual strength parameters for joint infilling materials within the lavas. Rock Mass Rating (RMR) and Geological Strength Index (GSI) values were calculated and converted to Mohr-Coulomb strength parameters using the Hoek-Brown criterion. Backanalysis of known landslide scarps was used to derive strength parameters for brecciated rock masses and hydrothermally altered rock masses. Andesite lava flows have high intact strength (sigma(ci) = 184 +/- 50 MN m(-2); gamma = 24.7 +/- 0.3 kN m(-3)) and typically 3 wide, infilled joint sets, one parallel to flow direction and two steeply inclined, with spacings of 0.3-1.7 m. Joints are rough, with estimated friction angles for clean joints of phi(j) = 42-47 degrees. Joint infill materials are clayey silts derived from weathering of wall rocks and primary volcanic sources; they have low plastic (54%) and liquid (84%) limits and residual strength values Of C-r=0 kN m(-2) and phi(r)=23.9 +/- 3.1 degrees. RMR values range from 70 to 73, giving calculated strength parameters of c'=1161-3391 kN m(-2) and phi'=50.5-62.3 degrees. Backanalysis suggests brecciated rock masses have c'=0 kN m(-2) and phi'=35.4 degrees, whereas GSI observations in the field suggest higher cohesion (c'=306-719 kN m(-2)) and a range of friction angles bracketing the backanalysed result (phi'=30.6-41.7 degrees). Hydrothermally altered rock masses have c'=369 kN m(-2) and phi'=14.9 degrees, indicating considerable loss of strength, especially frictional resistance, compared with the fresh lava units. Values measured at outcrop scale in this study are in keeping with other published values for similar volcanic edifices; backanalysed data suggest weaker rock mass properties than those determined at outcrop. This is interpreted as a scale issue, whereby rock mass characteristics of a large rock mass (crater wall scale) are weaker than those of small outcrops, due in part to the overestimation of friction angle from measurements on small exposures. (c) 2005 Elsevier B.V. All rights reserved.