2009
DOI: 10.1029/2009jb006339
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Organization of volcanic plumbing through magmatic lensing by magma chambers and volcanic loads

Abstract: [1] The development of discrete volcanic centers reflects a focusing of magma ascending from the source region to the surface. We suggest that this organization occurs via mechanical interactions between magma chambers, volcanic edifices, and dikes and that the stresses generated by these features may localize crustal magma transport before the first eruption occurs. We develop a model for the focusing or ''lensing'' of rising dikes by magma chambers beneath a free surface, and we show that chambers strongly m… Show more

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Cited by 77 publications
(63 citation statements)
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“…Reservoir inflation via sustained pipe flow through the crust has been shown to reproduce surface uplift at other volcanic zones, such as Laguna del Maule (Le Mevel et al, 2016). Alternatively, quasi-steady intrusion of dikes toward a long-lived reservoir at the level of the APMB could explain observations (e.g., Karlstrom et al, 2009). Assuming fluctuations of surface displacement are due to transient mass addition, we require that transport must be occurring at rates on the order of tens of kilometers per year, either as quasi-steady flow or semi-regular dike intrusions focused into a reservoir zone over multiple decades.…”
Section: Modeling Temporal Variationmentioning
confidence: 99%
“…Reservoir inflation via sustained pipe flow through the crust has been shown to reproduce surface uplift at other volcanic zones, such as Laguna del Maule (Le Mevel et al, 2016). Alternatively, quasi-steady intrusion of dikes toward a long-lived reservoir at the level of the APMB could explain observations (e.g., Karlstrom et al, 2009). Assuming fluctuations of surface displacement are due to transient mass addition, we require that transport must be occurring at rates on the order of tens of kilometers per year, either as quasi-steady flow or semi-regular dike intrusions focused into a reservoir zone over multiple decades.…”
Section: Modeling Temporal Variationmentioning
confidence: 99%
“…The free surface is ultimately responsible for generating stress concentrations that produce ring fractures and caldera collapse (Gudmundsson, 1998;Marti et al, 2008). As the chamber grows larger laterally, the free surface begins to project a larger capture zone at depth as the load better approximates a surface load (Karlstrom et al, 2009). Because estimates based on dissolved H 2 O in melt inclusions place the top of the Mazama chamber at ∼5 km with a thickness of perhaps several kilometers Mandeville et al, 2009), we can expect that free surface stress effects are non-negligible.…”
Section: Magma Chamber Mechanicsmentioning
confidence: 98%
“…The spatial extent and influence of viscoelastic host rocks depends on the enthalpy influx and thermal state of host rocks. Karlstrom et al (2010) show that a stability criterion is the ratio of a chamber pressurization timescale τ E ≈ P V Ch /E Q and relaxation timescale τ VE ≈ μ Ch /E (defining a Deborah number De = τ VE /τ E ). Here V Ch is the chamber volume, Q the magma influx rate, E is Young's modulus of host rocks, and μ Ch the viscosity of the shell.…”
Section: Magma Chamber Mechanicsmentioning
confidence: 99%
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“…The use of more realistic physics-based models that could better interpret field observations such as those that could account for magma rheology and compressibility (e.g., Rivalta and Segall, 2008;Segall, 2011, 2013;Segall, 2016;Got et al, 2017) are then highly encouraged. Data assimilation can also be extended to models representing other plumbing mechanism such as magma reservoirs recharged by dikes at depth (e.g., Karlstrom et al, 2009) or even those eruptions that are related to dike intrusions.…”
Section: Toward More Realistic Physics-based Modelsmentioning
confidence: 99%