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1 School of Geological Sciences, Kingston University, Kingston-upon-Thames KT1 2EE, UK (e-mail: n.petford{at}kingston.ac.uk)
2 School of Applied Physics, Kingston University, Kingston-upon-Thames, KT1 2EE, UK
Recent thermal and fluid dynamical models have shown that density-driven ascent of isoviscous granitic melt through the crust in narrow dykes is geologically instantaneous, provided the role of suspended crystals is ignored. However, it is well known that solids in suspension can aVect significantly the rheology and hence flow properties of magmas, leading to the subjective criticism that granite ascent and emplacement rates based on simple dyke transport models may be unrealistic. By estimating the magnitude of shear stresses developed during continuous flow in a 6 m wide granitic dyke, we show yield strengths in excess of 104 pascals are required to stop flow entirely if the pressure gradient driving the flow is high. Using granular flow theory, we show how fluctuations in particle velocity in the shear field can be used to predict the rheological behaviour of magmas with crystal contents (solidosity) in the range 0.1<
<0.25.
Specimen calculations for the solidosity and fluctuation on particle velocity for ascending granitic magmas show that the energy associated with these irregular movements is much greater than that expected on purely Brownian grounds. We find no clear correlation between viscosity ì and the yield strength, and while it is possible that magma has curious, unexpected bonding properties, magmatic suspensions where the grain size is on the scale of centimetres (e.g. some coarsely porphyritic magmas), low estimated Bagnold numbers (c. 10"8) render Bingham flow models inappropriate. Self-organization of the flow into a crystal-poor margin and crystal-rich core (flow differentiation) by diffusion of particles towards the region of minimal shear results in the familiar plug-type flow profiles traditionally associated with an inherent yield strength. Shear-enhanced diffusion is an inevitable consequence of granular flow that leads to flow differentiation, providing a simple mechanistic explanation for high concentrations of pheoncrysts in the cores of porphyritic dykes (Bagnold effect). Deviation from simple Newtonian flow is unlikely to be significant until the magma has stopped ascending and emplacement begins.
Key Words: granites • magmas • dykes • viscosity • fluctuations
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  J. D. CLEMENS and N. PETFORD Granitic melt viscosity and silicic magma dynamics in contrasting tectonic settings Journal of the Geological Society, 1999; 156: 1057 - 1060. [Abstract] [PDF]
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