Abstract
Abstract. P-wave refraction seismics is a key method in permafrost research but its applicability to low-porosity rocks, which constitute alpine rock walls, has been denied in prior studies. These studies explain p-wave velocity changes in freezing rocks exclusively due to changing velocities of pore infill, i.e. water, air and ice. In existing models, no significant velocity increase is expected for low-porosity bedrock. We postulate, that mixing laws apply for high-porosity rocks, but freezing in confined space in low-porosity bedrock also alters physical rock matrix properties. In the laboratory, we measured p-wave velocities of 22 decimetre-large low-porosity (< 10%) metamorphic, magmatic and sedimentary rock samples from permafrost sites with a natural texture (> 100 micro-fissures) from 25 °C to −15 °C in 0.3 °C increments close to the freezing point. When freezing, p-wave velocity increases by 11–166% perpendicular to cleavage/bedding and equivalent to a matrix velocity increase from 11–200% coincident to an anisotropy decrease in most samples. The expansion of rigid bedrock upon freezing is restricted and ice pressure will increase matrix velocity and decrease anisotropy while changing velocities of the pore infill are insignificant. Here, we present a modified Timur's two-phase-equation implementing changes in matrix velocity dependent on lithology and demonstrate the general applicability of refraction seismics to differentiate frozen and unfrozen low-porosity bedrock.
Highlights
Rock samples are classified according to their lithology into three metamorphic, two igneous and two sedimentary rock clusters
We propose to incorporate the physical concept of freezing in confined space into geophysical modelling of p-wave velocities and present data (1) of p-wave measurements of 22 different alpine rocks, (2) evaluate the influence of ice pressure on seismic velocities, (3) determine anisotropic decrease due to ice pressure and (4) ex20 tend Timur’s (1968) 2-phase model for alpine rocks: 1. All rock samples show a p-wave velocity increase dependent on lithology due to freezing
P-wave velocity increases due to freezing are dominated by an increase of the velocity of the rock matrix while changes in pore-infill velocities are insignificant
Summary
20 Most polar and many mountainous regions of the earth are underlain by permafrost and are susceptible to Climate Change (IPCC, 2007; Nogues-Bravo et al, 2007). Permafrost is a thermally defined phenomenon referring to ground that remains below 0 ◦C for at least two consecutive years (NRC-Permafrost-Subcommitee, 1988). Rock permafrost is not synonymous with perennially frozen rock due to freezing point depres-. Ice develops in pores and cavities (Hallet et al, 1991) and affects the thermal, hydraulic and mechanical properties of rocks. Climate Change acts to degrade permafrost and, alters permafrost distribution. In mountainous regions, degrading permafrost rock walls are considered to be a major hazard due to rockfall activity and slow rock deformation (Gruber and Haeberli, 2007; Krautblatter et 5 al., 2012)
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