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PREMA

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( 87 Sr&#x2F; 86 Sr)0–ε Nd  diagram for basites from the Kropotkin Ridge. <span class="search-highlight">PREMA</span>,...
Published: 01 August 2010
Fig. 9. ( 87 Sr/ 86 Sr)0–ε Nd diagram for basites from the Kropotkin Ridge. PREMA, moderately depleted mantle source, EM-I, Nd-enriched mantle source, EM-II, 86 Sr-enriched mantle source. Other designations follow Fig. 8 .
Journal Article
Journal: Palynology
Published: 14 October 2024
Palynology (2024) 48 (4): 2365735.
FIGURES | View All (7)
Journal Article
Published: 01 October 2008
Clays and Clay Minerals (2008) 56 (5): 494–504.
FIGURES | View All (7)
Series: Geological Society, London, Special Publications
Published: 01 January 2004
DOI: 10.1144/GSL.SP.2004.223.01.02
EISBN: 9781862394711
... Graben and Scania (probably also Bornholm and the North Sea) is geochemically similar to the Prevalent Mantle (PREMA) component. Rifting and magmatism in the area is likely to be due to local decompression and thinning of highly asymmetric lithosphere in responses to regional stretching north...
FIGURES | View All (13)
Journal Article
Published: 01 October 2015
Geochemical Perspectives (2015) 4 (2): 95–96.
... is observed between these genera, but all mix with a prevalent mantle component, PREMA, that contributes to many if not all plumes. Although the mantle comprising plumes also show evidence of previous melt extraction events, the more prominent chemical signature is of material anciently recycled from...
Journal Article
Published: 01 March 2015
Russ. Geol. Geophys. (2015) 56 (3): 379–401.
..., ferromonticellite, phlogopite, and magnetite. They are enriched in P2O5 (up to 6.4 wt.%), Sr (up to 3000–4500 ppm; Sr/Ba ~ 5–7), and REE + Y (up to 800 ppm) and show evidence for liquation genesis. The predominant magmatic source (ε Nd ( T ) = 5–7) was moderately depleted PREMA, possibly combined with E-MORB and EM...
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Journal Article
Published: 01 August 2012
Russ. Geol. Geophys. (2012) 53 (8): 721–735.
... 5 (up to 3.6 wt.%), Sr (∼2500–5500 ppm), and REE (up to ∼2000 ppm) and are, presumably, of liquation genesis. A PREMA-type plume component was a predominant magma source for the complex (ɛ Nd ( T ) = +6.56 to +6.85). According to isotope data ( 87 Sr/ 86 Sr( T ) ∼ 0.7032–0.7039; δ 18 O ∼ 7.5–14.9...
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Journal Article
Published: 01 July 2010
Russ. Geol. Geophys. (2010) 51 (7): 774–784.
... that of the oceanic lithosphere. Late Mesozoic magmas originated mainly from hydrated mantle sources with isotopic compositions typical of PREMA or EM-II. In the Early Cenozoic (50 Ma), the anomalous mantle was considerably less active than in the Early Cretaceous. Magmatic melts were generated only in two mantle...
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Journal Article
Published: 01 September 2024
Russ. Geol. Geophys. (2024) 65 (9): 1041–1051.
...–15.56, 208 Pb/ 204 Pb = 38.40–39.01) indicate both heterogeneity of mantle mafic melts and their partial crust contamination. Doleritic magma was presumably generated predominantly from a substance from a moderately depleted mantle source, which is similar in isotopic composition to the PREMA component...
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Image
The Nd and Sr isotope ratios in the West Transbaikalian basites ( 1 ), EM-I...
Published: 01 June 2011
Fig. 9. The Nd and Sr isotope ratios in the West Transbaikalian basites ( 1 ), EM-I ( 2 ), EM-II ( 3 ), and OIB, after Faure (1986) . PREMA—depleted mantle source.
Image
Isotopic composition of Nd and Sr in basaltoids of the Minusa depression. D...
Published: 01 September 2024
basin ( Callegaro et al., 2021 ). Mantle components PREMA, DMM, EM 1, and EM 2 and Mantle array field follow literature data ( Zindler and Hart, 1986 ; Hart et al., 1992 ; Stracke et al., 2005 ).
Journal Article
Published: 01 December 2003
Russ. Geol. Geophys. (2003) 44 (12): 1270–1279.
... that within-plate rocks may be derived from the originally undepleted or weakly depleted PREMA sources which predominate in the lower mantle or from enriched EM1 and EM2 sources, which most likely correspond to fragments of ancient lithosphere buried in the mantle [ 16 ]. These ideas are consistent...
FIGURES
Journal Article
Published: 01 January 2023
Russ. Geol. Geophys. (2023) 64 (1): 45–61.
... shown that the isotope composition of the magmatic melt formed from a PREMA source with a minor contribution of the latter. The mantle source for the studied basanites is assumed to be olivine pyroxenites (Ol + Cpx + Grt). The generation of basaltic melts occurred under the influence of a mantle plume...
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Nd–Sr isotope correlation diagram for the bulk samples of high-alumina pyro...
Published: 01 October 2022
– silicate Earth as a whole, EMI – enriched mantle of type I, PREMA – prevalent mantle.
Journal Article
Published: 01 March 2021
Russ. Geol. Geophys. (2021) 62 (03): 291–305.
...–1.06 GPa, and the sequence of mineral crystallization has been established. The obtained Sr and Nd isotope data indicate that the basanitic magmas were generated from material with PREMA and EMI isotope parameters. © 2021, V.S. Sobolev IGM, Siberian Branch of the RAS 2021 V.S. Sobolev IGM, Siberian...
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Journal Article
Published: 01 August 2020
Russ. Geol. Geophys. (2020) 61 (8): 838–857.
.... The volcanic area of southern Transbaikalia (Khentei Ridge) resulted, most likely, from the mantle plume impact on the lithosphere. The age of this area is estimated at 3.51 Ma. PREMA was the main mantle source for these volcanics, and the contribution of HIMU was strongly subordinate. In geochemical features...
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Silicoflagellate (black line) and diatom (gray line,  Finkel et al. 2005 ) ...
Published: 01 June 2012
and Prema (1996) and Perch-Nielsen (1985) compilation.
Journal Article
Published: 01 May 2019
Russ. Geol. Geophys. (2019) 60 (5): 451–462.
... produced, most likely, from genetically related heterogeneous sources with ε Nd ( T ) varying from 3.0 to 6.3 and from –0.5 to 6.5, respectively, which might be due to the mixing of the depleted (PREMA) and enriched (EM) mantle materials. Initial ratios 207 Pb/ 206 Pb ≈ 0.89 and 208 Pb/ 206 Pb ≈ 2.15 in K...
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Image
(A) Oxygen isotope content of apatite from coarse-grained dolomite of the B...
Published: 15 October 2019
—depleted mid-oceanic ridge basalt source mantle; EM I—enriched mantle I; EM II—enriched mantle II; PREMA—prevalent mantle; HIMU—high U/ Pb ratio mantle .DMM, EMI, EMII, PREMA, and HIMU are mantle end-member components ( Zindler and Hart, 1986 ). (C) Sm-Nd isochron age of apatite from coarse-grained
Journal Article
Published: 01 July 2018
Russ. Geol. Geophys. (2018) 59 (7): 718–744.
... suggest that the intrusions proceeded under interaction of the PREMA + EM/OIB mantle plume and the suprasubductional lithospheric IAB mantle. The mantle–crust interaction led to the heterogeneous isotopic composition of neodymium in the magma source (ɛ Nd ( T ) ~ 3.5–5.4). The mixing of different mantle...
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