Quantifying the sensitivity of post-glacial sea level change to laterally varying viscosity

Crawford, Ophelia; Al-Attar, David; Tromp, Jeroen; Mitrovica, J. X.; Austermann, Jacqueline; Lau, H. C. P.

doi:10.1093/gji/ggy184

Cited by 42 publications

(73 citation statements)

References 51 publications

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“…A more rigorous understanding of these issues requires inversions of 3D viscosity analyzed through a 3D sensitivity (Fréchet kernel) analysis. In this regard, a series of theoretical studies that build toward the application of adjoint methods to the GIA problem (e.g., Al‐Attar & Tromp, ; Crawford et al, ; Crawford et al, ) provide a framework for tackling the 3D viscosity problem. The conclusions herein may be seen as a motivation for the continued development of such methods.…”

Section: Discussionmentioning

confidence: 99%

Inferences of Mantle Viscosity Based on Ice Age Data Sets: The Bias in Radial Viscosity Profiles Due to the Neglect of Laterally Heterogeneous Viscosity Structure

et al. 2018

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Inferences of mantle viscosity using glacial isostatic adjustment (GIA) data are hampered by data sensitivity to the space‐time geometry of ice cover. A subset of GIA data is relatively insensitive to this ice history: the Fennoscandian relaxation spectrum (FRS), postglacial decay times in Canada and Scandinavia, and the rate of change of the degree‐2 zonal harmonic of the geopotential ( J̇2). These geographically limited data have been inverted to constrain the radial (one‐dimensional [1D]) mantle viscosity profile. We explore potential biases in these 1D inversions introduced by neglecting a three‐dimensional (3D) viscosity structure. We perform 1D Bayesian inversions of synthetic GIA data generated from Earth models with realistic 3D variations in mantle viscosity and lithospheric thickness and compare results to the 1D viscosity profile associated with the 3D model used to generate the synthetics. Differences between these two 1D profiles reflect GIA data resolution and biasing introduced by neglecting, in the inversions, a 3D viscosity structure. We focus on the second issue, demonstrating that the largest bias occurs within the upper mantle (in particular, the transition zone). This remains consistent when varying inversion parameters (e.g., prior/starting models) and the 1D/3D viscosity fields adopted in generating the synthetics. Inversions of individual data sets show 3D biasing increases for data exhibiting shallower (thus more localized) sensitivity to viscosity. Of the data considered herein, inversions of the FRS are subject to the largest bias followed by decay time data. The bias is minimal for J̇2, as its deeper sensitivity is accompanied by broader averaging of structure in radial and lateral directions.

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Section: Discussionmentioning

confidence: 99%

Inferences of Mantle Viscosity Based on Ice Age Data Sets: The Bias in Radial Viscosity Profiles Due to the Neglect of Laterally Heterogeneous Viscosity Structure

et al. 2018

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“…Lastly, we note that sea-level responses in our simulations are governed by a spherically symmetric Earth model, a characteristic shared by nearly all implementations of the sea-level theory due to the computational expense of computing sea-level responses with a laterally varying 3-D Earth model (e.g., Latychev et al, 2005;de Boer et al, 2017;Gomez et al, 2018;Crawford et al, 2018). This approach necessarily neglects several things that may affect sealevel changes in Taiwan, including lateral variations in mantle and lithospheric properties (viscosity, elasticity, density, thickness), brittle crustal deformation, and crustal underplating, and other tectonic processes (e.g., Suppe, 1984).…”

Section: Sensitivity To Sediment Redistribution History and Earth Modelmentioning

confidence: 99%

Sea-level responses to rapid sediment erosion and deposition in Taiwan

Ruetenik

Ferrier

Creveling

et al. 2020

Earth and Planetary Science Letters

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Numerous studies have shown that sediment deposition can perturb sea level by several meters over millennial timescales by modifying the gravity field, crustal elevation, and sediment thickness. Relatively few studies have focused on the complementary role of erosion on sea-level change despite its effects on the same quantities, partly because many rapidly eroding mountains are too far from shorelines to strongly perturb sea level at the coast. Taiwan, a mountainous island eroding rapidly within tens of km of the coast, offers an opportunity to investigate the joint influences of rapid onshore erosion and rapid offshore deposition on sea-level change. Here we develop a sediment loading history for Taiwan since the previous interglacial (~120 ka) by compiling published erosion and deposition rate measurements and by applying a geometric marine sediment deposition and compaction model for sites without deposition rate measurements. We use the resulting sediment redistribution history to drive sea-level responses in a gravitationally self-consistent sea-level model. Our simulations show that the effects of rapid onshore erosion outweigh the effects of rapid offshore deposition along Taiwan's east coast.

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“…The background viscosity structure is scaled from a tomographic model of seismic shear wave-speed variations using a simple empirical relation. Results for other depths and times, when combined, define sensitivity kernels that can be used to invert RSL data from Tahiti for an optimal 3D viscosity model with uncertainty estimates (Crawford et al 2018).…”

Section: Towards Improved Gia Modelsmentioning

confidence: 99%

Advances in glacial isostatic adjustment modeling

2019

PAGES Mag

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Quantifying the sensitivity of post-glacial sea level change to laterally varying viscosity

Cited by 42 publications

References 51 publications

Inferences of Mantle Viscosity Based on Ice Age Data Sets: The Bias in Radial Viscosity Profiles Due to the Neglect of Laterally Heterogeneous Viscosity Structure

Inferences of Mantle Viscosity Based on Ice Age Data Sets: The Bias in Radial Viscosity Profiles Due to the Neglect of Laterally Heterogeneous Viscosity Structure

Sea-level responses to rapid sediment erosion and deposition in Taiwan

Advances in glacial isostatic adjustment modeling

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