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Schedule Problem Set #3- on line, due Monday Oct.25 Updated Syllabus (with new PS due date) MidTerm #1, Thursday, Oct. 20 study guide online this week Field Trip 8:00 am Saturday, Oct 22. Rheology, con’t Review: Two basic rock rheologies: 1) 2)
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Schedule Problem Set #3- on line, due Monday Oct.25 Updated Syllabus (with new PS due date) MidTerm #1, Thursday, Oct. 20 study guide online this week Field Trip 8:00 am Saturday, Oct 22
Rheology, con’t Review: Two basic rock rheologies: 1) 2) Key attritutes of each rheology 1) something to do with stress/strain 2) something to do with strain and time 3) something to do with recoverability strain rate
Creep curve Behavior of rocks to compression is not simple. Deforms over time => Elastic: Non-linear viscous Linear viscous Non linear viscous Instant deformation =>
Elastic behaviour and shear stress Shear modulus (G): resistance of elastic solids to shearing. Divide shear stress (ss) by shear strain (g) G = shear modulus = ss/g ss
Elastic behaviour and dilation (important in seismology) Bulk Modulus (K): resistance of elastic solids to dilation. Another relationship between stress and volume change Poisson’s Ratio n n=-etransverse/eaxial (perpendicular and parallel to compression direction) Common values 0 to 0.5 (fully compressible, to fully incompressible)
Poisson’s ratio, Greek letter nu (n). This describes the amount that a rock bulges as it shortens. The ratio describes the ratio of lateral strain to longitudinal strain: n = -etrans/eaxial Poisson’s ratio is unit-less, since it is a ratio of extension. What does a low ratio mean? What does a high ratio mean? Typical values for n are: Fine-grained limestone: 0.25 Apilite: 0.2 Oolitic limestone: 0.18 Granite: 0.11 Calcareous shale: 0.02 Biotite schist: 0.01
Poisson’s ratio If we shorten a granite and measure how much it bulges, we see that we can shorten a granite, but it may not be compensated by an increase in rock diameter. So stress did not produce the expected lateral bulging. Somehow volume decreases and stress was stored until the rock exploded! Thus low values of Poisson’s ratio are significant.
rocks and deformation Deformation experiments Concrete strength test video
Nature rocks and deformation Deformation experiments • Specimens are drilled out cores that are ‘machined’ to have perfectly parallel and smooth ends. • Specimens are carefully measured to determine their initial length (lo) and diameter (to get initial cross-sectional area, Ao). • Specimens are jacketed with weak material - copper or plastic.
rocks and deformation Deformation experiments • Experiments are carried out in steel pressure vessels. • Confining pressure (s2 = s3) is often supplied by fluid that surrounds the specimen. • Load is applied to end of rock, differential stress (s1 – s3) is the important measurement • Pore-fluid pressure can also be varied.
Nature rocks and deformation Deformation experiments • Pressure chamber – confining pressure (Pc) • Pore-fluid pressure (Pf) • Difference between Pc and Pf (Pc –Pf ) is effective pressure, Pe • Adjust pressures
Natural rocks and deformation Deformation experiments Strength vs Confining Pressure Elastic Deformation Non-Elastic Deformation Fracture Compression stress-strain curves at various confining pressure at 25°C What is confining pressure in real world? Lithostatic pressure High confining pressure & rock strength
Nature rocks and deformation Deformation experiments Strength vs Confining Pressure Changing confining pressure on various rock types Confining Pressure= Lithostatic pressure
Nature rocks and deformation Deformation experiments Strength vs Confining Pressure At Higher Temperatures Elastic Deformation Non-Elastic Deformation Fracture Compression stress-strain curves at various confining pressure at 400°C
Nature rocks and deformation Deformation experiments Role of temperature and rock strength Yield strength decreases with increasing temperatures Yield strength: the maximum stress that a rock can support elastically (recoverable) Temperature & rock strength
Nature rocks and deformation Deformation experiments Summary: Experiments demonstrate that rocks have higher strength with increasing pressure (i.e., depth). However, in the Earth’s crust, as pressure increases, so does the temperature (both typically increase with depth). At some depth, rock strength decreases with depth. (strength-depth diagrams) Temperature & rock strength