An analysis of isostasy in the world's oceans 1. Hawaiian‐Emperor Seamount Chain

Watts, A. B.

doi:10.1029/jb083ib12p05989

Cited by 535 publications

(470 citation statements)

References 40 publications

Supporting

Mentioning

437

Contrasting

Unclassified

Order By: Relevance

“…More important, a compilation of estimates of admittance from a variety of regions ( Figure 9) shows observed values of admittance to be consistently positive [e.g., Bayasgalan et al, 2005;D'Agostino and McKenzie, 1999;Komut et al, 2012;Fielding and McKenzie, 2012;McKenzie and Bowin, 1976;McKenzie and Fairhead, 1997;Tiley et al, 2003;Watts, 1978]. We are not aware of a single study reporting negative values for the Earth.…”

Section: Discussionmentioning

confidence: 91%

Effects of a low‐viscosity lower crust on topography and gravity at convergent mountain belts during gravitational instability of mantle lithosphere

Molnár

Houseman

2015

JGR Solid Earth

View full text Add to dashboard Cite

We examine the gravitational stability of a stratified structure consisting of a low-density crust through which viscosity decreases exponentially, over a denser mantle lithosphere of constant viscosity, which in turn overlies an inviscid, slightly less dense layer like the asthenosphere. The most important aspect of the viscosity structure is the contrast in viscosity at the Moho. Surface uplift above a mantle downwelling is greatest when the viscosity contrast at the Moho is negligible. The surface is depressed when the viscosity of the lowermost crust is much greater than mantle viscosity. For a wide range of viscosity structures, calculated gravity anomalies and in particular admittances (ratios of the Fourier transform of gravity to that of topography) produced by Rayleigh-Taylor instability differ markedly from those observed across convergent mountain belts. In particular, whereas values of calculated admittance are negative, or very small, observed admittances are consistently positive. Thus, if downwelling of mantle lithosphere directly beneath mountain ranges plays an important role in the construction of mountain belts, it cannot be the main process that induces crustal thickening.

show abstract

Section: Discussionmentioning

confidence: 91%

Effects of a low‐viscosity lower crust on topography and gravity at convergent mountain belts during gravitational instability of mantle lithosphere

Molnár

Houseman

2015

JGR Solid Earth

View full text Add to dashboard Cite

show abstract

“…By comparing observed gravity anomalies with calculated anomalies based on simple elastic or viscoelastic models it has been possible to estimate the effective elastic thickness and how it may vary with crustal age. The main results of these studies, summarized in Watts (1978), is that surface loads formed at or near mid-ocean ridge crests are associated with relatively small values of the effective elastic thickness while surface loads formed on relatively old lithospheric plates are associated with relatively large values. Figure 2 is a plot of "isostatic response function" for the East Pacific rise crest and Hawaiian-Emperor seamount chain in the Pacific ocean.…”

Section: Discussionmentioning

confidence: 99%

“…The smaller value can be explained by taking into account the age of the Seamounts along the chain [Clague and Jarrard, 1973]. In a recent study, Watts [1978] observed the correlation between gravity and bathymetry data obtained from surface ships over several sections of the Pacific Ocean: the East Pacific Rise, the Hawaiian-Emperor Seamounts, and the Kuril Rise. He deduced that the relevant factor related to flexural rigidity is the age of the lithosphere at the time of loading.…”

Section: Short Wavelength Studymentioning

confidence: 99%

See 1 more Smart Citation

Applications of Geodesy to Geodynamics an International Symposium

Mueller

1977

Bull. Geodesique

View full text Add to dashboard Cite

“…For this purpose, the relationship between geoid/ gravity and the topography in the spectral domain (admittance / coherence) is utilized for better understanding the isostatic response of the topographic loads, and for studies related to thermo-mechanical characterization of the oceanic lithosphere and/or sub-lithospheric upper mantle. Several researchers have effectively used this approach i) for evaluating isostatic response of the oceanic lithospheric using free-air gravity/ geoid and bathymetry admittance function (e.g., McKenzie and Bowin, 1976;Watts, 1978;Black and McAdoo, 1988); ii) for estimation of flexural rigidity of continental lithosphere through Bouguer gravity and topography coherence function (Forsyth, 1985;Lowry and Smith, 1994;McKenzie and Fairhead, 1997;Simons et al, 2000;Swain and Kirby, 2003). In the present study, we analyzed the admittance between bathymetry and residual geoid on two wavelength scales, one using degree-10 residual geoid for modeling upper mantle convection processes, and other using degree-50 residual geoid for understanding mode of isostatic compensation along the 85°E and Ninetyeast ridges.…”

Section: Admittance / Coherence Analysismentioning

confidence: 99%

Lithosphere structure and upper mantle characteristics below the Bay of Bengal

et al. 2016

View full text Add to dashboard Cite

SUMMARY:The oceanic lithosphere in the Bay of Bengal (BOB) formed 80 -120 Ma following the breakup of eastern Gondwanaland. Since its formation, it has been affected by the emplacement of two long N-S trending linear aseismic ridges (85 o E and Ninetyeast) and by the loading of ca.20-km of sediments of the Bengal Fan. Here, we present the results of a combined spatial and spectral domain analysis of residual geoid, bathymetry and gravity data constrained by seismic reflection and refraction data. Self-consistent geoid and gravity modeling defined by temperature-dependent mantle densities along a N-S transect in the BOB region revealed that the depth to the Lithosphere-Asthenosphere boundary (LAB) deepens steeply from 77 km in the south to 127 km in north, with the greater thickness being anomalously thick compared to the lithosphere of similar-age beneath the Pacific Ocean. The Geoid-Topography Ratio (GTR) analysis of the 85°E and Ninetyeast ridges indicate that they are compensated at shallow depths.

show abstract

An analysis of isostasy in the world's oceans 1. Hawaiian‐Emperor Seamount Chain

Cited by 535 publications

References 40 publications

Effects of a low‐viscosity lower crust on topography and gravity at convergent mountain belts during gravitational instability of mantle lithosphere

Effects of a low‐viscosity lower crust on topography and gravity at convergent mountain belts during gravitational instability of mantle lithosphere

Applications of Geodesy to Geodynamics an International Symposium

Lithosphere structure and upper mantle characteristics below the Bay of Bengal

Contact Info

Product

Resources

About