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No Unique Scaling Law for Igneous Dikes

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posted on 2022-12-02, 15:21 authored by SPA Gill, RJ Walker, KJW McCaffrey, C Greenfield
In linear elastic fracture mechanics (LEFM), veins, dikes, and sills grow in length when the stress intensity factor (Formula presented.) at the tip reaches a critical value: the host rock fracture toughness (Formula presented.). This criterion is applied broadly in LEFM models for crack growth and it is often assumed that the pressure inside the crack is uniform. When applied to intrusion length versus thickness scaling, a significant issue arises in that derived (Formula presented.), which is about 100–1,000 times that of measured (Formula presented.) values for rocks at upper crustal depths. The same scaling relationships applied to comparatively short mineral vein data gives (Formula presented.), approaching the expected range. Here we propose that intrusions preserve non-equilibrated pressures as cracks controlled by kinetics, and therefore cannot be treated in continuum with fracture-controlled constant pressure (equilibrium) structures such as veins, or many types of scaled analogue model. Early stages of dike growth (inflation) give rise to increasing length and thickness, but magma pressure gradients within intrusions may serve to drive late-stage lengthening at the expense of maximum thickness (relaxation). For cracks in 2D, we find that intrusion scaling in non-equilibrium growth is controlled by the magma injection rate and initial dike scaling, effective (2D) host rock modulus, magma viscosity and cooling rate, which are different for all individual intrusions and sets of intrusions. A solidified intrusion can therefore achieve its final dimensions via many routes, with relaxation acting as a potentially significant factor, hence there is no unique scaling law for dike intrusions.

Funding

Funding for this work was provided by an APEX award (Academies Partnership in Supporting Excellence in Cross-disciplinary research award)supported by the Royal Society, theBritish Academy, the Leverhulme Trust, and the Royal Academy of Engineering. Funding was awarded to SG, and purely as financial support for a research fellowship. CG was supported by aDaphne Jackson Fellowship, funded by the NERC and the University of Leicester.The authors thank the Editor (Douglas Schmitt), Associate Editor, and two anonymous reviewers, for their constructive remarks, and look forward to further discussion in the future.

History

Citation

Gill, S. P. A. and Walker, R. J. and McCa?rey, K. J. W. and Green?eld, C. (2022) 'No Unique Scaling Law for Igneous Dikes.', Journal of Geophysical Research: Solid Earth, 127 (9). e2022JB024120.

Author affiliation

School of Engineering; School of Geography, Geology, and the Environment

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  • VoR (Version of Record)

Published in

JOURNAL OF GEOPHYSICAL RESEARCH-SOLID EARTH

Volume

127

Issue

9

Publisher

AMER GEOPHYSICAL UNION

issn

2169-9313

eissn

2169-9356

Acceptance date

2022-08-23

Copyright date

2022

Available date

2022-12-02

Language

English

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