Plume-lithosphere interaction, and the formation of fibrous diamonds

M.W. Broadley; H. Kagi; Raymond Burgess; Dmitry Zedgenizov; Sami Mikhail; Matthieu Almayrac; Alexey Ragozin; Bogdan Pomazansky; Hirochika Sumino

doi:10.7185/geochemlet.1825

Plume-lithosphere interaction, and the formation of fibrous diamonds

M.W. Broadley, H. Kagi, Raymond Burgess, Dmitry Zedgenizov, Sami Mikhail, Matthieu Almayrac, Alexey Ragozin, Bogdan Pomazansky, Hirochika Sumino

Research output: Contribution to journal › Article › peer-review

Abstract

Fluid-inclusions in diamond provide otherwise inaccessible information on the origin and nature of carbonaceous fluid(s) in the mantle. Here we evaluate the role of subducted volatiles in diamond-formation within the Siberian cratonic lithosphere. Specifically, we focus on the halogen (Cl, Br and I) and noble gas (He, Ne and Ar) geochemistry of fluids trapped within cubic, coated and cloudy fibrous diamonds from the Nyurbinskaya kimberlite, Siberia. Our data show Br/Cl and I/Cl ratios consistent with involvement of altered oceanic crust, suggesting subduction-derived fluids have infiltrated the Siberian lithosphere. ³He/⁴He ranging from 2 to 11R_A, indicates the addition of a primordial mantle component to the SCLM. Mantle plumes may therefore act as a trigger to re-mobilise subducted carbon-rich fluids from the sub-continental lithospheric mantle, and we argue this may be an essential process in the formation of fluid-rich diamonds, and kimberlitic magmatism.

Original language	English
Pages (from-to)	26-30
Journal	Geochemical Perspectives Letters
Volume	8
DOIs	https://doi.org/10.7185/geochemlet.1825
Publication status	Published - 1 Oct 2018

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Planetary Science
Gilmour, J., Joy, K., Lyon, I., Burgess, R., Jones, R., Tartese, R., Holland, G., Clay, P., Crowther, S., Pernet-Fisher, J., Ruzie, L., Assis Fernandes, V., MacArthur, J., Nottingham, M., Bell, S., Baker, E., Hartley, M., Neave, D. & Snape, J.
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title = "Plume-lithosphere interaction, and the formation of fibrous diamonds",

abstract = "Fluid-inclusions in diamond provide otherwise inaccessible information on the origin and nature of carbonaceous fluid(s) in the mantle. Here we evaluate the role of subducted volatiles in diamond-formation within the Siberian cratonic lithosphere. Specifically, we focus on the halogen (Cl, Br and I) and noble gas (He, Ne and Ar) geochemistry of fluids trapped within cubic, coated and cloudy fibrous diamonds from the Nyurbinskaya kimberlite, Siberia. Our data show Br/Cl and I/Cl ratios consistent with involvement of altered oceanic crust, suggesting subduction-derived fluids have infiltrated the Siberian lithosphere. 3He/4He ranging from 2 to 11RA, indicates the addition of a primordial mantle component to the SCLM. Mantle plumes may therefore act as a trigger to re-mobilise subducted carbon-rich fluids from the sub-continental lithospheric mantle, and we argue this may be an essential process in the formation of fluid-rich diamonds, and kimberlitic magmatism.",

author = "M.W. Broadley and H. Kagi and Raymond Burgess and Dmitry Zedgenizov and Sami Mikhail and Matthieu Almayrac and Alexey Ragozin and Bogdan Pomazansky and Hirochika Sumino",

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doi = "10.7185/geochemlet.1825",

language = "English",

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T1 - Plume-lithosphere interaction, and the formation of fibrous diamonds

AU - Broadley, M.W.

AU - Kagi, H.

AU - Burgess, Raymond

AU - Zedgenizov, Dmitry

AU - Mikhail, Sami

AU - Almayrac, Matthieu

AU - Ragozin, Alexey

AU - Pomazansky, Bogdan

AU - Sumino, Hirochika

PY - 2018/10/1

Y1 - 2018/10/1

N2 - Fluid-inclusions in diamond provide otherwise inaccessible information on the origin and nature of carbonaceous fluid(s) in the mantle. Here we evaluate the role of subducted volatiles in diamond-formation within the Siberian cratonic lithosphere. Specifically, we focus on the halogen (Cl, Br and I) and noble gas (He, Ne and Ar) geochemistry of fluids trapped within cubic, coated and cloudy fibrous diamonds from the Nyurbinskaya kimberlite, Siberia. Our data show Br/Cl and I/Cl ratios consistent with involvement of altered oceanic crust, suggesting subduction-derived fluids have infiltrated the Siberian lithosphere. 3He/4He ranging from 2 to 11RA, indicates the addition of a primordial mantle component to the SCLM. Mantle plumes may therefore act as a trigger to re-mobilise subducted carbon-rich fluids from the sub-continental lithospheric mantle, and we argue this may be an essential process in the formation of fluid-rich diamonds, and kimberlitic magmatism.

AB - Fluid-inclusions in diamond provide otherwise inaccessible information on the origin and nature of carbonaceous fluid(s) in the mantle. Here we evaluate the role of subducted volatiles in diamond-formation within the Siberian cratonic lithosphere. Specifically, we focus on the halogen (Cl, Br and I) and noble gas (He, Ne and Ar) geochemistry of fluids trapped within cubic, coated and cloudy fibrous diamonds from the Nyurbinskaya kimberlite, Siberia. Our data show Br/Cl and I/Cl ratios consistent with involvement of altered oceanic crust, suggesting subduction-derived fluids have infiltrated the Siberian lithosphere. 3He/4He ranging from 2 to 11RA, indicates the addition of a primordial mantle component to the SCLM. Mantle plumes may therefore act as a trigger to re-mobilise subducted carbon-rich fluids from the sub-continental lithospheric mantle, and we argue this may be an essential process in the formation of fluid-rich diamonds, and kimberlitic magmatism.

U2 - 10.7185/geochemlet.1825

DO - 10.7185/geochemlet.1825

M3 - Article

VL - 8

SP - 26

EP - 30

JO - Geochemical Perspectives Letters

JF - Geochemical Perspectives Letters

SN - 2410-339X

ER -

Plume-lithosphere interaction, and the formation of fibrous diamonds

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