Coupled dynamics and evolution of primordial and recycled heterogeneity in Earth's lower mantle

Gülcher, Anna; Ballmer, Maxim D.; Tackley, P. J.

doi:10.5194/se-12-2087-2021

Cited by 18 publications

(20 citation statements)

References 125 publications

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“…Later-stage partial melting induced by hot anomalies in a largely solidified mantle leads to small-scale heterogeneity as different rock components melt under different conditions and have different affinity to partition into the molten phase (e.g., Hofmann 1997). Such processes compete with mantle convective stirring that tends to homogenise lateral variation, but the mixing time scales in the mantle are large and compositional heterogeneity occurs likely across multiple scales in the Earth's present mantle (e.g., Tkalčić et al 2015), as is also supported by modelling studies (Gülcher et al 2021). However, terrestrial plate tectonics continuously induces new heterogeneity by deep crustal subduction, which may be less relevant to Venus without plate tectonics.…”

Section: Mineralogy and Compositional Variationmentioning

confidence: 93%

Dynamics and Evolution of Venus’ Mantle Through Time

et al. 2022

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The dynamics and evolution of Venus’ mantle are of first-order relevance for the origin and modification of the tectonic and volcanic structures we observe on Venus today. Solid-state convection in the mantle induces stresses into the lithosphere and crust that drive deformation leading to tectonic signatures. Thermal coupling of the mantle with the atmosphere and the core leads to a distinct structure with substantial lateral heterogeneity, thermally and compositionally. These processes ultimately shape Venus’ tectonic regime and provide the framework to interpret surface observations made on Venus, such as gravity and topography. Tectonic and convective processes are continuously changing through geological time, largely driven by the long-term thermal and compositional evolution of Venus’ mantle. To date, no consensus has been reached on the geodynamic regime Venus’ mantle is presently in, mostly because observational data remains fragmentary. In contrast to Earth, Venus’ mantle does not support the existence of continuous plate tectonics on its surface. However, the planet’s surface signature substantially deviates from those of tectonically largely inactive bodies, such as Mars, Mercury, or the Moon. This work reviews the current state of knowledge of Venus’ mantle dynamics and evolution through time, focussing on a dynamic system perspective. Available observations to constrain the deep interior are evaluated and their insufficiency to pin down Venus’ evolutionary path is emphasised. Future missions will likely revive the discussion of these open issues and boost our current understanding by filling current data gaps; some promising avenues are discussed in this chapter.

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Section: Mineralogy and Compositional Variationmentioning

confidence: 93%

Dynamics and Evolution of Venus’ Mantle Through Time

et al. 2022

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“…While we have not included the effects of a dense, primordial layer in our simulations, we do not refute the potential for such compositions to exist in the mantle and play a role in LLSVP formation. Studies which combine both primordial and recycled OC material (Ballmer et al., 2016; Gülcher et al., 2021; Jones et al., 2021) will also benefit from including the effects of radiogenic heating in each of the compositions (Citron et al., 2020).…”

Section: Discussionmentioning

confidence: 99%

“…The first is that LLSVPs are composed of dense primordial material (Deschamps et al., 2011; Garnero & McNamara, 2008; Labrosse et al., 2007; M. Li & McNamara, 2018) and the second is that they formed from the accumulation of recycled oceanic crust (henceforth referred to as OC) (Christensen & Hofmann, 1994; Coltice & Ricard, 1999; Tackley, 2011). A third scenario arises from this, where LLSVPs may comprise heterogeneity from both recycled OC and primordial material, a so‐called basal melange (Gülcher et al., 2021; Jones et al., 2021; Tackley, 2012).…”

Section: Introductionmentioning

confidence: 99%

The Stability of Dense Oceanic Crust Near the Core‐Mantle Boundary

2023

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Seismic tomography models have discerned the presence of two mantle structures close to the core-mantle interface characterized by low seismic velocities. These large low-shear velocity provinces (LLSVPs) sit beneath Africa and the Pacific plate and exhibit a shear velocity anomaly of δlnV s ≈ −2%. Spatially, they are both voluminous and broad (Cottaar & Lekić, 2016), with seismic tomography models showing high power in spherical harmonic degree 2 and to a lesser extent degree 3 structures (Koelemeijer et al., 2016;Ritsema et al., 2011) in the lower mantle. These structures exist within and above the D" layer and may extend >1,000 km into the mantle from the core-mantle boundary (CMB) (He & Wen, 2009;Lekic et al., 2012), with the African LLSVP being significantly taller than the Pacific LLSVP (Ni et al., 2002;Yuan & Li, 2022). Mantle plumes are claimed to cluster around their edges (Thorne et al., 2004) potentially entraining material to be sampled by melting beneath ocean islands. Despite the morphology of LLSVPs being well constrained, increasingly accurate measurements of their material properties and possible direct links to the surface via plumes, their origin and composition remain a matter of debate. This is because the very characteristics that define LLSVPs have a non-unique source; the velocity anomaly may originate thermally, chemically, or thermo-chemically. Consequently there are competing theories over the nature of LLSVPs, are they of a predominantly thermal origin (D. R. Davies et al., 2015;

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“…Giuliani et al ( 2021 ) noted that the PREMA component found in most kimberlite sources may be contained within LLSVPs. However, the distribution of PREMA in the mantle remains uncertain; for example, "blobs/streaks" of ancient material are also modeled to exist and persist throughout the ambient mantle ( Ballmer et al, 2017;Becker et al, 1999;Brandenburg et al, 2008;Gülcher et al, 2021;Jones et al, 2021 ).…”

Section: Mantle Plume-driven Geochemical Enrichment Of the Kaavi-kuop...mentioning

confidence: 99%

Geodynamic and Isotopic Constraints on the Genesis of Kimberlites, Lamproites and Related Magmas From the Finnish Segment of the Karelian Craton

Dalton

Giuliani

Hergt

et al. 2022

Geochem Geophys Geosyst

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Despite the scientific and economic significance of kimberlites and related magmas, their origin is unclear. Here, we address this issue using whole‐rock and perovskite‐derived Sr‐Nd‐Hf isotopes for the three occurrences of kimberlite, lamproites and ultramafic lamprophyres (UMLs) in Finland. Mesoproterozoic olivine lamproites at Lentiira‐Kuhmo and UMLs at Kuusamo have different isotopic signatures yet were emplaced contemporaneously at 1,200 Ma in response to an extensional regime linked to the Baltica‐Laurentia breakup. The low εNd(i) and εHf(i) values of the olivine lamproites are consistent with an enriched subcontinental lithospheric mantle (SCLM) source while UML compositions are intermediate between those of typical kimberlites and lamproites and are interpreted to reflect mixing of asthenospheric melts and ∼10%–15% of melts sourced from metasomatized SCLM. The ∼750 Ma Kuusamo kimberlites, are probably linked to the mantle plume activity that initiated Rodinia's break‐up, exhibiting homogenous isotopic compositions which mirror the prominent Geodynamic and Source Constraints for ∼1,200 Ma Olivine Lamproite and Ultramafic Lamprophyre Magmatism in Eastern Finland (PREMA)‐like signature of kimberlites globally. By contrast, ∼620–585 Ma Kaavi‐Kuopio kimberlites show limited range in εNd(i) and 87Sr/86Sr(i) but have remarkably heterogeneous εHf(i) (+6.5 to −6.3) with a temporal trend toward lower εHf(i) values. While the Kuusamo kimberlites erupted during the early stage of continental break‐up, the Kaavi‐Kuopio kimberlites were emplaced when Rodinia break‐up was completed, coeval with formation of the Central Iapetus large igneous province. Magmas forming the Kaavi‐Kupio kimberlites may have formed from an upwelling mantle source similar to PREMA modified by increasing incorporation (up to 10%) of recycled crustal material through time accounting for the trend toward lower εHf(i) in these kimberlites.

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Coupled dynamics and evolution of primordial and recycled heterogeneity in Earth's lower mantle

Cited by 18 publications

References 125 publications

Dynamics and Evolution of Venus’ Mantle Through Time

Dynamics and Evolution of Venus’ Mantle Through Time

The Stability of Dense Oceanic Crust Near the Core‐Mantle Boundary

Geodynamic and Isotopic Constraints on the Genesis of Kimberlites, Lamproites and Related Magmas From the Finnish Segment of the Karelian Craton

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