Thermal structure due to solid-state flow in the mantle wedge beneath arcs

Kelemen, P. B.; Rilling, J.; Parmentier, E. M.; Mehl, L.; Hacker, Bradley R.

doi:10.1029/138gm13

Cited by 187 publications

(191 citation statements)

References 104 publications

(140 reference statements)

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“…The compositional disequilibrium characteristics of the augites suggest that the Hohxil high-Mg andesites were likely derived by interaction between melts and mantle (e.g., Rapp et al, 1999;Yogodzinski and Kelemen, 1998). However, the origin of the melts requires further clarification, given that similar melts have been attributed to partial melting of delaminated or subducted continental crust (e.g., Gao et al, 2004;Wang et al, 2006bWang et al, , 2008cXu et al, 2008), subducted basaltic oceanic crust, or sediments (e.g., Kay et al, 1993;Kelemen et al, 2003;Shimoda et al, 1998;Tatsumi, 2001;Tatsumi and Hanyu, 2003;Yogodzinski and Kelemen, 1998;Yogodzinski et al, 1994Yogodzinski et al, , 1995.…”

Section: Petrogenesismentioning

confidence: 99%

Late Triassic high-Mg andesite/dacite suites from northern Hohxil, North Tibet: Geochronology, geochemical characteristics, petrogenetic processes and tectonic implications

Wang

Chung

et al. 2011

Lithos

101

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Section: Petrogenesismentioning

confidence: 99%

Late Triassic high-Mg andesite/dacite suites from northern Hohxil, North Tibet: Geochronology, geochemical characteristics, petrogenetic processes and tectonic implications

Wang

Chung

et al. 2011

Lithos

101

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“…Localized regions of low viscosity caused by high water or melt content in the mantle wedge could allow the hot mantle to advect to shallower depths and thereby decrease the length of the coupled plate boundary [Kelemen et al, 2003], or could decrease the magnitude of the dynamic pressure in the wedge corner [Billen et al, 2003]. Both effects would lead to steeper slab dips.…”

Section: Other Factors Affecting Slab Dynamicsmentioning

confidence: 99%

“…The thermal structure of the plate directly above the slab is most important for the slab evolution. While the age of overriding plates varies significantly, the island arc region is thought to have temperatures of 1200-1400°C at depths of 50 km due in part to convective erosion from melt and volatile weakening of the overriding lithosphere [Kelemen et al, 2003;Arcay et al, 2007; A.-M. Cagnioncle et al, The effect of solid flow above a subducting slab on water distribution and melting at convergent plate boundaries, submitted to Journal of Geophysical Research, 2007]. Therefore a warm and thin overriding plate is appropriate and it is assigned an initial thermal structure determined by a half-space cooling model for a 40 my old plate.…”

Section: Model Setupmentioning

confidence: 99%

Rheologic controls on slab dynamics

Billen

Hirth

2007

Geochem Geophys Geosyst

191

186

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[1] Several models have been proposed to relate slab geometry to parameters such as plate velocity or plate age. However, studies on the observed relationships between slab geometry and a wide range of subduction parameters show that there is not a simple global relationship between slab geometry and any one of these other subduction parameters for all subduction zones. Numerical and laboratory models of subduction provide a method to explore the relative importance of different physical processes in determining subduction dynamics. Employing 2-D numerical models with a viscosity structure constrained by laboratory experiments for the deformation of olivine, we show that the observed range in slab dip and the observed trends between slab dip and convergence velocity, subducting plate age, and subduction duration can be reproduced without trench motion (i.e., slab roll-back) for locations away from slab edges. Successful models include a stiff slab that is 100-1000 times more viscous than previous estimates from models of plate bending, the geoid, and global plate motions. We find that slab dip in the upper mantle depends primarily on slab strength and plate boundary coupling, with a small dependence on subducting plate age. Once the slab sinks into the lower mantle the primary processes controlling slab evolution are (1) the ability of the stiff slab to transmit stresses up dip, (2) resistance to slab descent into the higherviscosity lower mantle, and (3) subduction-induced flow in the mantle-wedge corner.

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“…The Triassic to Jurassic arc is exposed in four volcanic and plutonic sections in the Chugach Mountains, the Talkeetna Mountains, the Kodiak archipelago and the Alaska Peninsula (Figure 1). Previous research has principally focused on the Chugach Mountains, which preserve a faulted crustal section from residual subarc mantle to subaerial volcanic rocks [DeBari and Coleman, 1989;Kelemen et al, 2003aKelemen et al, , 2003bMehl et al, 2003;Behn and Kelemen, 2006;Greene et al, 2006;Hacker et al, 2008]. The Jurassic batholith on the Alaska Peninsula is distinctly more felsic than the crustal section in the Chugach Mountains and has the potential to provide new insight into the role of silicic magmas in intraoceanic settings.…”

Section: Introductionmentioning

confidence: 99%

Intermediate to felsic middle crust in the accreted Talkeetna arc, the Alaska Peninsula and Kodiak Island, Alaska: An analogue for low‐velocity middle crust in modern arcs

et al. 2010

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Seismic profiles of several modern arcs have identified thick, low‐velocity midcrustal layers (Vp = 6.0–6.5 km/s) that are interpreted to represent intermediate to felsic plutonic crust. The presence of this silicic crust is surprising given the mafic composition of most primitive mantle melts and could have important implications for the chemical evolution and bulk composition of arcs. However, direct studies of the middle crust are limited by the restricted plutonic exposures in modern arcs. The accreted Talkeetna arc, south central Alaska, exposes a faulted crustal section from residual subarc mantle to subaerial volcanic rocks of a Jurassic intraoceanic arc and is an ideal place to study the intrusive middle crust. Previous research on the arc, which has provided insight into a range of arc processes, has principally focused on western exposures of the arc in the Chugach Mountains. We present new U‐Pb zircon dates, radiogenic isotope data, and whole‐rock geochemical analyses that provide the first high‐precision data on large intermediate to felsic plutonic exposures on Kodiak Island and the Alaska Peninsula. A single chemical abrasion–thermal ionization mass spectrometry analysis from the Afognak pluton yielded an age of 212.87 ± 0.19 Ma, indicating that the plutonic exposures on Kodiak Island represent the earliest preserved record of Talkeetna arc magmatism. Nine new dates from the extensive Jurassic batholith on the Alaska Peninsula range from 183.5 to 164.1 Ma and require a northward shift in the Talkeetna arc magmatic axis following initial emplacement of the Kodiak plutons, paralleling the development of arc magmatism in the Chugach and Talkeetna mountains. Radiogenic isotope data from the Alaska Peninsula and the Kodiak archipelago range from ɛNd(t) = 5.2 to 9.0 and 87Sr/86Srint = 0.703515 to 0.703947 and are similar to age‐corrected data from modern intraoceanic arcs, suggesting that the evolved Alaska Peninsula plutons formed by extensive differentiation of arc basalts with little or no involvement of preexisting crustal material. The whole‐rock geochemical data and calculated seismic velocities suggest that the Alaska Peninsula represents an analogue for the low‐velocity middle crust observed in modern arcs. The continuous temporal record and extensive exposure of intermediate to felsic plutonic rocks in the Talkeetna arc indicate that evolved magmas are generated by repetitive or steady state processes and play a fundamental role in the growth and evolution of intraoceanic arcs.

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Thermal structure due to solid-state flow in the mantle wedge beneath arcs

Cited by 187 publications

References 104 publications

Late Triassic high-Mg andesite/dacite suites from northern Hohxil, North Tibet: Geochronology, geochemical characteristics, petrogenetic processes and tectonic implications

Late Triassic high-Mg andesite/dacite suites from northern Hohxil, North Tibet: Geochronology, geochemical characteristics, petrogenetic processes and tectonic implications

Rheologic controls on slab dynamics

Intermediate to felsic middle crust in the accreted Talkeetna arc, the Alaska Peninsula and Kodiak Island, Alaska: An analogue for low‐velocity middle crust in modern arcs

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