Magmatic processes at slow spreading ridges: implications of the RAMESSES experiment at 57° 45′N on the Mid-Atlantic Ridge

Sinha, M. C.; Constable, Steven; Peirce, C.; White, Antony; Heinson, Graham; MacGregor, Lucy; Navin, D. A.

doi:10.1046/j.1365-246x.1998.00704.x

Cited by 97 publications

(112 citation statements)

References 59 publications

Supporting

Mentioning

105

Contrasting

Unclassified

Order By: Relevance

“…Calvert (1995) suggested the presence of a small magma body beneath the segment immediately south of the Kane TF, but the seismic images available were of poor quality. A combined seismic and electromagnetic study along the Reykjanes Ridge (57845 ′ N) did identify an AML located about 2.5 km beneath a large AVR (Sinha et al 1998). In addition, a large swarm of hydroacoustically and teleseismically recorded earthquakes in 2001 in the Lucky Strike segment near 37820 ′ N was interpreted by Dziak et al (2002) as a magma/dyke emplacement event into the crust beneath the Lucky Strike volcano, a c. 1 km high edifice in the segment centre; however, there was no along-axis migration of seismicity to indicate lateral propagation of a dyke and subsequent surveys showed no indication of eruption on the seafloor.…”

Section: Geophysical Properties Of Discontinuities and Ridge Segmentsmentioning

confidence: 99%

Tectonic and magmatic segmentation of the Global Ocean Ridge System: a synthesis of observations

Carbotte

Smith

Cannat

et al. 2015

View full text Add to dashboard Cite

Mid-ocean ridges display tectonic segmentation defined by discontinuities of the axial zone, and geophysical and geochemical observations suggest segmentation of the underlying magmatic plumbing system. Here, observations of tectonic and magmatic segmentation at ridges spreading from fast to ultraslow rates are reviewed in light of influential concepts of ridge segmentation, including the notion of hierarchical segmentation, spreading cells and centralized v. multiple supply of mantle melts. The observations support the concept of quasi-regularly spaced principal magmatic segments, which are 30-50 km long on average at fast-to slow-spreading ridges and fed by melt accumulations in the shallow asthenosphere. Changes in ridge properties approaching or crossing transform faults are often comparable with those observed at smaller offsets, and even very small discontinuities can be major boundaries in ridge properties. Thus, hierarchical segmentation models that suggest large-scale transform fault-bounded segmentation arises from deeper level processes in the asthenosphere than the finer-scale segmentation are not generally supported. The boundaries between some but not all principal magmatic segments defined by ridge axis geophysical properties coincide with geochemical boundaries reflecting changes in source composition or melting processes. Where geochemical boundaries occur, they can coincide with discontinuities of a wide range of scales.Discovery and interpretations of mid-ocean ridge (MOR) segmentation: historical review

show abstract

Section: Geophysical Properties Of Discontinuities and Ridge Segmentsmentioning

confidence: 99%

Tectonic and magmatic segmentation of the Global Ocean Ridge System: a synthesis of observations

Carbotte

Smith

Cannat

et al. 2015

View full text Add to dashboard Cite

show abstract

“…The velocity of normal oceanic lower crust is well defined around 6.9-7.0 km/s, but it is actually not easy to explain this observation from first principles [Korenaga et [57]" ---Note that the interpretation of ref. [57] has recently been challenged by Korenaga [2007, JGR]. In this regard, it's important to emphasize the virtue of the combined use of seismic and electromagnetic methods.…”

Section: Figs 1-2: Please Indicate the Border Of The Interpreted Sermentioning

confidence: 99%

Geophysical characterisation of the ocean–continent transition at magma-poor rifted margins

Minshull

2008

Comptes Rendus. Géoscience

View full text Add to dashboard Cite

Geophysical characterisation of the ocean-continent transition (OCT) at magma-poor rifted margins has focused primarily on the determination of P wave velocities using wide-angle seismic techniques. Such experiments have shown that the OCT is heterogeneous, but that typically velocities increase gradually with depth from ~5.0 km/s at top basement to ~8.0 km/s at ~5 km deeper, without a large and abrupt Moho transition. The velocity variation with depth is similar to that of old fracture zone crust, and appears to differ from that of oceanic crust formed at ultra-slow spreading rates, though sampling of the latter is limited.Typically, the OCT is characterised by weakly lineated, low amplitude magnetic anomalies; the interpretation of these anomalies remains controversial. The oceanward limit of the OCT remains poorly defined on many margins.

show abstract

“…2 for locations (25-29 are not in the map area). (a) Iceland: 1-6 with increasing distance from the hotspot (Darbyshire et al 2000a); (b) platform and crust from Kolbeinsey Ridge (Hooft et al 2006); (c) Reykjanes Ridge (Bunch and Kennett 1980;Rizert and Jacoby 1985;Sinha et al 1998); (d) East Greenland Margin: 15-transition zone, 16-thick oceanic crust (Korenaga et al 2000); (e) Faeroe-Iceland Ridge (Bohnhoff and Makris 2004;Smallwood et al 1999;White et al 2008); (f) Hatton Bank (White et al 2008); (g) Vøring Margin (Mutter and Mutter 1993); (h) average oceanic crust (Bown and White 1994). [Colour online.…”

Section: Upper Crust Of Icelandmentioning

confidence: 99%

Crustal accretion of thick mafic crust in Iceland: implications for volcanic rifted margins

Karson

2016

Can. J. Earth Sci.

View full text Add to dashboard Cite

Rifting near hotspots results in mantle melting to create thick mafic igneous crust at volcanic rifted margins (VRMs). This mafic crust is transitional between rifted continental crust with mafic intrusions landward and oceanic crust into which it grades seaward. Seismic velocities, crustal drilling, and exhumed margins show that the upper crust in these areas is composed of basaltic lava erupted in subaerial to submarine conditions intruded by downward increasing proportions of dikes and sparse gabbroic intrusions. The lower crust of these regions is not exposed but is inferred from seismic velocities (Vp > 6.5 km/sec) and petrological constraints to be gabbroic to ultramafic in composition. Limited access to crustal sections generated along VRMs have raised questions regarding the composition and structure of this transitional crust and how it evolves during the early stages of rifting and subsequent seafloor spreading. Active processes in Iceland provide a glimpse of subaerial spreading with the creation of a thick (40-25 km) mafic igneous crust that may be analogous to the transitional crust of VRMs. Segmented rift zones that propagate away from the Iceland hotspot, migrating transform fault zones, and rift-parallel strike-slip faults create a complex plate boundary zone in the upper, brittle crust. These structures may be decoupled from underlying lower crustal gabbroic rocks that are capable of along-axis flow that smooths-out crustal thickness variations. Similar processes may be characteristic of the early history of VRMs and volcanic hotspot ridges related to rifting and seafloor spreading proximal to hotspots. Résumé :De la distension à proximité de points chauds génère une fusion du manteau créant une épaisse croûte ignée mafique aux marges de divergence des volcans (VRM). Cette croûte mafique constitue une transition entre la croûte continentale de divergence comportant des intrusions mafiques du côté continental et la croûte océanique dans laquelle elle s'intègre vers le large. Les vitesses sismiques, les forages dans la croûte et les bordures exhumées montrent que, dans ces secteurs, la croûte supérieure est composée de lave basaltique ayant fait éruption sous des conditions subaériennes à sous-marines et elle a été pénétrée par des intrusions gabbroïques éparses et des dykes dont les proportions augmentent vers le bas. La croûte inférieure de ces régions n'affleure pas mais selon les vitesses sismiques (Vp > 6,5 km/sec) et les contraintes pétrologiques elle serait de composition gabbroïque à ultramafique. L'accès limité aux sections de la croûte générées le long des VRM a soulevé des questions quant à la composition et la structure de cette croûte de transition et de son évolution durant les premiers stades de distension et d'étalement subséquent du plancher océanique. Des processus actifs en Islande fournissent un aperçu de l'étalement subaérien avec la création d'une épaisse (40-25 km) croûte ignée mafique qui pourrait être analogue à la croûte de transition des VRM. Des zones de rift ...

show abstract

Magmatic processes at slow spreading ridges: implications of the RAMESSES experiment at 57° 45′N on the Mid-Atlantic Ridge

Cited by 97 publications

References 59 publications

Tectonic and magmatic segmentation of the Global Ocean Ridge System: a synthesis of observations

Tectonic and magmatic segmentation of the Global Ocean Ridge System: a synthesis of observations

Geophysical characterisation of the ocean–continent transition at magma-poor rifted margins

Crustal accretion of thick mafic crust in Iceland: implications for volcanic rifted margins

Contact Info

Product

Resources

About