Glacial isostatic adjustment in the static gravity field of Fennoscandia

Root, Bart; Wal, Wouter van der; Novák, Pavel; Ebbing, J.; Vermeersen, L. L. A.

doi:10.1002/2014jb011508

Cited by 34 publications

(37 citation statements)

References 44 publications

(76 reference statements)

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“…This corroborates our assumption that compensated masses are situated in the region between the LAB and the Moho. The compensation is shown to represent the global gravity observations well in most of the spectral domain (Root et al 2015). The separation between the lithosphere and asthenosphere is obtained from Hamza & Vieira (2012), which is based on global databases of heat flow (Vieira & Hamza 2010) and crustal structure (Laske et al 2013).…”

Section: Gravity-based Model Of the Lithospherementioning

confidence: 99%

“…Kaban et al 2004;Root et al 2015;Herceg et al 2016). However, due to the intrinsic non-uniqueness of gravity modelling the solutions need to be constrained, which introduces uncertainties in the final model.…”

Section: Introductionmentioning

confidence: 99%

“…Second, the gravity signal of the crust needs to be removed from the observations (Kaban et al 2004) to reveal the lithosphere. Errors in the used crustal model lead to uncertainty in the lithosphere solutions (Panasyuk & Hager 2000;Kaban et al 2004;Root et al 2015). For example, the global crustal model CRUST1.0 (Laske et al 2013) suffers from lack of data in large parts of the world.…”

Section: Introductionmentioning

confidence: 99%

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Comparing gravity-based to seismic-derived lithosphere densities: a case study of the British Isles and surrounding areas

et al. 2016

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S U M M A R YLithospheric density structure can be constructed from seismic tomography, gravity modelling, or using both data sets. The different approaches have their own uncertainties and limitations. This study aims to characterize and quantify some of the uncertainties in gravity modelling of lithosphere densities. To evaluate the gravity modelling we compare gravity-based and seismic velocity-based approaches to estimating lithosphere densities. In this study, we use a crustal model together with lithospheric isostasy and gravity field observations to estimate lithosphere densities. To quantify the effect of uncertainty in the crustal model, three models are implemented in this study: CRUST1.0, EuCrust-07 and a high-resolution P-wave velocity model of the British Isles and surrounding areas. Different P-wave velocity-to-density conversions are used to study the uncertainty in these conversion methods. The crustal density models are forward modelled into gravity field quantities using a method that is able to produce spherical harmonic coefficients. Deep mantle signal is assumed to be removed by removing spherical harmonic coefficients of degree 0-10 in the observed gravity field. The uncertainty in the resulting lithosphere densities due to the different crustal models is ±110 kg m −3 , which is the largest uncertainty in gravity modelling. Other sources of uncertainty, such as the V P to density conversion (±10 kg m −3 ), long-wavelength truncation (±5 kg m −3 ), choice of reference model (<±20 kg m −3 ) and Lithosphere Asthenosphere Boundary uncertainty (±30 kg m −3 ), proved to be of lesser importance. The resulting lithosphere density solutions are compared to density models based on a shear wave velocity model. The comparison shows that the gravity-based models have an increased lateral resolution compared to the tomographic solutions. However, the density anomalies of the gravity-based models are three times higher. This is mainly due to the high resolution in the gravity field. To account for this, the gravity-based density models are filtered with a spatial Gaussian filter with 200 km half-width, which results in similar density estimates (±35 kg m −3 ) with the tomographic approach. Lastly, the gravity-based density is used to estimate laterally varying conversion factors, which correlate with major tectonic regions. The independent gravity-based solutions could help in identifying different compositional domains in the lithosphere, when compared to the tomographic solutions.

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Section: Gravity-based Model Of the Lithospherementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Comparing gravity-based to seismic-derived lithosphere densities: a case study of the British Isles and surrounding areas

et al. 2016

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“…As a reference profile we use VM5a (Peltier and Drummond, 2008), which is an iteration of the VM2 profile that is used in the creation of ICE-5G (Peltier, 2004). As alternative profiles we select profiles that have been shown by Root et al (2015b) to provide a good fit to sea level data, GPS, and GRACE (Gravity Recovery and Climate Experiment) data in Fennoscandia. That study found two viscosity profiles: one with higher viscosities in the upper and lower mantle and one with lower viscosities.…”

Section: Model Inputs: Viscosity and Ice Loadingmentioning

confidence: 99%

“…That study found two viscosity profiles: one with higher viscosities in the upper and lower mantle and one with lower viscosities. The fact that sediment loading is not taken into account to obtain viscosity profiles in Root et al (2015b) will have a minor effect on our results given that three very different viscosity profiles are selected to account for uncertainty in viscosity. Out of those sets we select M8-128-150 and M4-16-80, where the first number denotes the upper mantle viscosity in 10 20 Pa s, the second number denotes the lower mantle viscosity in 10 20 Pa s, and the third number denotes the lithosphere thickness in kilometers.…”

Section: Model Inputs: Viscosity and Ice Loadingmentioning

confidence: 99%

The effect of sediment loading in Fennoscandia and the Barents Sea during the last glacial cycle on glacial isostatic adjustment observations

Wal

IJpelaar²

2017

Solid Earth

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Abstract. Models for glacial isostatic adjustment (GIA) routinely include the effects of meltwater redistribution and changes in topography and coastlines. Since the sediment transport related to the dynamics of ice sheets may be comparable to that of sea level rise in terms of surface pressure, the loading effect of sediment deposition could cause measurable ongoing viscous readjustment. Here, we study the loading effect of glacially induced sediment redistribution (GISR) related to the Weichselian ice sheet in Fennoscandia and the Barents Sea. The surface loading effect and its effect on the gravitational potential is modeled by including changes in sediment thickness in the sea level equation following the method of Dalca et al. (2013). Sediment displacement estimates are estimated in two different ways: (i) from a compilation of studies on local features (trough mouth fans, large-scale failures, and basin flux) and (ii) from output of a coupled ice-sediment model. To account for uncertainty in Earth's rheology, three viscosity profiles are used.It is found that sediment transport can lead to changes in relative sea level of up to 2 m in the last 6000 years and larger effects occurring earlier in the deglaciation. This magnitude is below the error level of most of the relative sea level data because those data are sparse and errors increase with length of time before present. The effect on present-day uplift rates reaches a few tenths of millimeters per year in large parts of Norway and Sweden, which is around the measurement error of long-term GNSS (global navigation satellite system) monitoring networks. The maximum effect on present-day gravity rates as measured by the GRACE (Gravity Recovery and Climate Experiment) satellite mission is up to tenths of microgal per year, which is larger than the measurement error but below other error sources. Since GISR causes systematic uplift in most of mainland Scandinavia, including GISR in GIA models would improve the interpretation of GNSS and GRACE observations there.

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GRACE gravity observations constrain Weichselian ice thickness in the Barents Sea

Root

Tarasov

Wal

2015

Geophysical Research Letters

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The Barents Sea is subject to ongoing postglacial uplift since the melting of the Weichselian ice sheet that covered it. The regional ice sheet thickness history is not well known because there is only data at the periphery due to the locations of Franz Joseph Land, Svalbard, and Novaya Zemlya surrounding this paleo ice sheet. We show that the linear trend in the gravity rate derived from a decade of observations from the Gravity Recovery and Climate Experiment (GRACE) satellite mission can constrain the volume of the ice sheet after correcting for current ice melt, hydrology, and far‐field gravitational effects. Regional ice‐loading models based on new geologically inferred ice margin chronologies show a significantly better fit to the GRACE data than that of ICE‐5G. The regional ice models contain less ice in the Barents Sea than present in ICE‐5G (5–6.3 m equivalent sea level versus 8.5 m), which increases the ongoing difficulty in closing the global sea level budget at the Last Glacial Maximum.

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Glacial isostatic adjustment in the static gravity field of Fennoscandia

Cited by 34 publications

References 44 publications

Comparing gravity-based to seismic-derived lithosphere densities: a case study of the British Isles and surrounding areas

Comparing gravity-based to seismic-derived lithosphere densities: a case study of the British Isles and surrounding areas

The effect of sediment loading in Fennoscandia and the Barents Sea during the last glacial cycle on glacial isostatic adjustment observations

GRACE gravity observations constrain Weichselian ice thickness in the Barents Sea

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