Geoscience Frontiers

Geoscience Frontiers

Volume 6, Issue 1, January 2015, Pages 3-22
Geoscience Frontiers

Research paper
Importance of initial buoyancy field on evolution of mantle thermal structure: Implications of surface boundary conditions

https://doi.org/10.1016/j.gsf.2014.05.004Get rights and content
Under a Creative Commons license
open access

Highlights

  • No need for dense chemical piles to generate stable mantle plumes above the LLSVPs.

  • Intraplate volcanism in the SE Pacific may be explained by small-scale convection.

  • Long-term Java-Indonesian subducting flow resembles current mantle structures.

  • 3-D convection models detect intrinsic deep-mantle buoyancy below the Perm Anomaly.

  • Models with a rigid surface preserve the initial thermally-dominated structure.

Abstract

Although there has been significant progress in the seismic imaging of mantle heterogeneity, the outstanding issue that remains to be resolved is the unknown distribution of mantle temperature anomalies in the distant geological past that give rise to the present-day anomalies inferred by global tomography models. To address this question, we present 3-D convection models in compressible and self-gravitating mantle initialised by different hypothetical temperature patterns. A notable feature of our forward convection modelling is the use of self-consistent coupling of the motion of surface tectonic plates to the underlying mantle flow, without imposing prescribed surface velocities (i.e., plate-like boundary condition). As an approximation for the surface mechanical conditions before plate tectonics began to operate we employ the no-slip (rigid) boundary condition. A rigid boundary condition demonstrates that the initial thermally-dominated structure is preserved, and its geographical location is fixed during the evolution of mantle flow. Considering the impact of different assumed surface boundary conditions (rigid and plate-like) on the evolution of thermal heterogeneity in the mantle we suggest that the intrinsic buoyancy of seven superplumes is most-likely resolved in the tomographic images of present-day mantle thermal structure. Our convection simulations with a plate-like boundary condition reveal that the evolution of an initial cold anomaly beneath the Java-Indonesian trench system yields a long-term, stable pattern of thermal heterogeneity in the lowermost mantle that resembles the present-day Large Low Shear Velocity Provinces (LLSVPs), especially below the Pacific. The evolution of subduction zones may be, however, influenced by the mantle-wide flow driven by deeply-rooted and long-lived superplumes since Archean times. These convection models also detect the intrinsic buoyancy of the Perm Anomaly that has been identified as a unique slow feature distinct from the two principal LLSVPs. We find there is no need for dense chemical ‘piles’ in the lower mantle to generate a stable distribution of temperature anomalies that are correlated to the LLSVPs and the Perm Anomaly. Our tomography-based convection simulations also demonstrate that intraplate volcanism in the south-east Pacific may be interpreted in terms of shallow small-scale convection triggered by a superplume beneath the East Pacific Rise.

Keywords

Dynamics: convection currents, and mantle plumes
Hotspots
Seismic tomography
Planetary tectonics
CMB topography
Perm Anomaly

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Peer-review under responsibility of China University of Geosciences (Beijing)