Diffusion-zoned pyroxenes in heterogeneous mantle lithosphere beneath the Dunedin Volcanic Group, New Zealand, and their implications for intraplate alkaline magma sources

Hayden Dalton; James Scott; Jingao Liu; Tod Earle Waight; D.G. Pearson; Marco Brenna; Petrus  Le Roux; J.M. Palin

doi:10.1130/l631.1

Diffusion-zoned pyroxenes in heterogeneous mantle lithosphere beneath the Dunedin Volcanic Group, New Zealand, and their implications for intraplate alkaline magma sources

Hayden Dalton, James Scott, Jingao Liu, Tod Earle Waight, D.G. Pearson, Marco Brenna, Petrus Le Roux, J.M. Palin

Geologi

20 Citationer (Scopus)

Abstract

An important task in assessing the magma source of an intraplate volcanic province is establishing the composition of the underlying lithospheric mantle. Pyroxenes in peridotite xenoliths from the ~10,000 km² Dunedin Volcanic Group in New Zealand reveal that the underlying lithospheric mantle is chemically and isotopically heterogeneous and has a complex thermal history. Portions of this mantle have light rare earth element-depleted clinopyroxene trace element concentrations and distinctly radiogenic Nd compositions (εNd_{(20 Ma)} ≥ + 15.5) with model depleted mantle ages that are ≥100 m.y. Older than the overlying Jurassic crust (type 1). The Nd isotopic composition of these moderately fertile domains is distinct from any Dunedin Volcanic Group magma, but the domains are embedded within enriched peridotitic mantle (type 2) that has formed through reaction with a light rare earth element-rich fluid that imparted an isotopic composition in strongly meta- somatized xenoliths of ⁸⁷Sr/⁸⁶Sr_{(20 Ma)} = 0.7028-0.7029, εNd_{(20 Ma)} = + 5.0 to + 5.1, and ²⁰⁶Pb/²⁰⁴Pb = 19.9 , ²⁰⁷Pb/²⁰⁴Pb = 15.5, and ²⁰⁸Pb/²⁰⁴Pb = 39.6. These isotope ratios overlap with the isotopically homogeneous high time-integrated U/Pb-like source signature of the host Dunedin Volcanic Group. However, all metasomatic and nonmetasomatic pyroxenes are zoned in temperature-sensitive elements (Al, Cr, Mg ± Ca), with trends indicating element exchange during cooling and the results of diffusion calculations implying that the zoning formed over hundreds of thousands to millions of years prior to late Oligocene-Miocene xenolith entrainment. These data, along with calculated pyroxene rare earth element homogenization diffusion rates, indicate that mantle metasomatism predated entrainment in the host magmas by millions of years. Furthermore, the presence of the cooling trends in all but one sample indicates that this upper lithosphere mantle preserves little or no sign of a rise in the geotherm at the time of magmatism. Zoning patterns in peridotite pyroxenes can therefore provide useful insight into the role of portions of the lithospheric mantle in formation of intraplate alkaline basalts.

Originalsprog	Engelsk
Tidsskrift	Lithosphere
Vol/bind	9
Udgave nummer	3
Sider (fra-til)	463-475
Antal sider	13
ISSN	1941-8264
DOI	https://doi.org/10.1130/l631.1
Status	Udgivet - 2017

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10.1130/l631.1

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title = "Diffusion-zoned pyroxenes in heterogeneous mantle lithosphere beneath the Dunedin Volcanic Group, New Zealand, and their implications for intraplate alkaline magma sources",

abstract = "An important task in assessing the magma source of an intraplate volcanic province is establishing the composition of the underlying lithospheric mantle. Pyroxenes in peridotite xenoliths from the ~10,000 km2 Dunedin Volcanic Group in New Zealand reveal that the underlying lithospheric mantle is chemically and isotopically heterogeneous and has a complex thermal history. Portions of this mantle have light rare earth element-depleted clinopyroxene trace element concentrations and distinctly radiogenic Nd compositions (εNd(20 Ma) ≥ + 15.5) with model depleted mantle ages that are ≥100 m.y. Older than the overlying Jurassic crust (type 1). The Nd isotopic composition of these moderately fertile domains is distinct from any Dunedin Volcanic Group magma, but the domains are embedded within enriched peridotitic mantle (type 2) that has formed through reaction with a light rare earth element-rich fluid that imparted an isotopic composition in strongly meta- somatized xenoliths of 87Sr/86Sr(20 Ma) = 0.7028-0.7029, εNd(20 Ma) = + 5.0 to + 5.1, and 206Pb/204Pb = 19.9 , 207Pb/204Pb = 15.5, and 208Pb/204Pb = 39.6. These isotope ratios overlap with the isotopically homogeneous high time-integrated U/Pb-like source signature of the host Dunedin Volcanic Group. However, all metasomatic and nonmetasomatic pyroxenes are zoned in temperature-sensitive elements (Al, Cr, Mg ± Ca), with trends indicating element exchange during cooling and the results of diffusion calculations implying that the zoning formed over hundreds of thousands to millions of years prior to late Oligocene-Miocene xenolith entrainment. These data, along with calculated pyroxene rare earth element homogenization diffusion rates, indicate that mantle metasomatism predated entrainment in the host magmas by millions of years. Furthermore, the presence of the cooling trends in all but one sample indicates that this upper lithosphere mantle preserves little or no sign of a rise in the geotherm at the time of magmatism. Zoning patterns in peridotite pyroxenes can therefore provide useful insight into the role of portions of the lithospheric mantle in formation of intraplate alkaline basalts.",

author = "Hayden Dalton and James Scott and Jingao Liu and Waight, {Tod Earle} and D.G. Pearson and Marco Brenna and {Le Roux}, Petrus and J.M. Palin",

year = "2017",

doi = "10.1130/l631.1",

language = "English",

volume = "9",

pages = "463--475",

journal = "Lithosphere",

issn = "1941-8264",

publisher = "The Geological Society of America",

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T1 - Diffusion-zoned pyroxenes in heterogeneous mantle lithosphere beneath the Dunedin Volcanic Group, New Zealand, and their implications for intraplate alkaline magma sources

AU - Dalton, Hayden

AU - Scott, James

AU - Liu, Jingao

AU - Waight, Tod Earle

AU - Pearson, D.G.

AU - Brenna, Marco

AU - Le Roux, Petrus

AU - Palin, J.M.

PY - 2017

Y1 - 2017

N2 - An important task in assessing the magma source of an intraplate volcanic province is establishing the composition of the underlying lithospheric mantle. Pyroxenes in peridotite xenoliths from the ~10,000 km2 Dunedin Volcanic Group in New Zealand reveal that the underlying lithospheric mantle is chemically and isotopically heterogeneous and has a complex thermal history. Portions of this mantle have light rare earth element-depleted clinopyroxene trace element concentrations and distinctly radiogenic Nd compositions (εNd(20 Ma) ≥ + 15.5) with model depleted mantle ages that are ≥100 m.y. Older than the overlying Jurassic crust (type 1). The Nd isotopic composition of these moderately fertile domains is distinct from any Dunedin Volcanic Group magma, but the domains are embedded within enriched peridotitic mantle (type 2) that has formed through reaction with a light rare earth element-rich fluid that imparted an isotopic composition in strongly meta- somatized xenoliths of 87Sr/86Sr(20 Ma) = 0.7028-0.7029, εNd(20 Ma) = + 5.0 to + 5.1, and 206Pb/204Pb = 19.9 , 207Pb/204Pb = 15.5, and 208Pb/204Pb = 39.6. These isotope ratios overlap with the isotopically homogeneous high time-integrated U/Pb-like source signature of the host Dunedin Volcanic Group. However, all metasomatic and nonmetasomatic pyroxenes are zoned in temperature-sensitive elements (Al, Cr, Mg ± Ca), with trends indicating element exchange during cooling and the results of diffusion calculations implying that the zoning formed over hundreds of thousands to millions of years prior to late Oligocene-Miocene xenolith entrainment. These data, along with calculated pyroxene rare earth element homogenization diffusion rates, indicate that mantle metasomatism predated entrainment in the host magmas by millions of years. Furthermore, the presence of the cooling trends in all but one sample indicates that this upper lithosphere mantle preserves little or no sign of a rise in the geotherm at the time of magmatism. Zoning patterns in peridotite pyroxenes can therefore provide useful insight into the role of portions of the lithospheric mantle in formation of intraplate alkaline basalts.

AB - An important task in assessing the magma source of an intraplate volcanic province is establishing the composition of the underlying lithospheric mantle. Pyroxenes in peridotite xenoliths from the ~10,000 km2 Dunedin Volcanic Group in New Zealand reveal that the underlying lithospheric mantle is chemically and isotopically heterogeneous and has a complex thermal history. Portions of this mantle have light rare earth element-depleted clinopyroxene trace element concentrations and distinctly radiogenic Nd compositions (εNd(20 Ma) ≥ + 15.5) with model depleted mantle ages that are ≥100 m.y. Older than the overlying Jurassic crust (type 1). The Nd isotopic composition of these moderately fertile domains is distinct from any Dunedin Volcanic Group magma, but the domains are embedded within enriched peridotitic mantle (type 2) that has formed through reaction with a light rare earth element-rich fluid that imparted an isotopic composition in strongly meta- somatized xenoliths of 87Sr/86Sr(20 Ma) = 0.7028-0.7029, εNd(20 Ma) = + 5.0 to + 5.1, and 206Pb/204Pb = 19.9 , 207Pb/204Pb = 15.5, and 208Pb/204Pb = 39.6. These isotope ratios overlap with the isotopically homogeneous high time-integrated U/Pb-like source signature of the host Dunedin Volcanic Group. However, all metasomatic and nonmetasomatic pyroxenes are zoned in temperature-sensitive elements (Al, Cr, Mg ± Ca), with trends indicating element exchange during cooling and the results of diffusion calculations implying that the zoning formed over hundreds of thousands to millions of years prior to late Oligocene-Miocene xenolith entrainment. These data, along with calculated pyroxene rare earth element homogenization diffusion rates, indicate that mantle metasomatism predated entrainment in the host magmas by millions of years. Furthermore, the presence of the cooling trends in all but one sample indicates that this upper lithosphere mantle preserves little or no sign of a rise in the geotherm at the time of magmatism. Zoning patterns in peridotite pyroxenes can therefore provide useful insight into the role of portions of the lithospheric mantle in formation of intraplate alkaline basalts.

U2 - 10.1130/l631.1

DO - 10.1130/l631.1

M3 - Journal article

SN - 1941-8264

VL - 9

SP - 463

EP - 475

JO - Lithosphere

JF - Lithosphere

IS - 3

ER -

Diffusion-zoned pyroxenes in heterogeneous mantle lithosphere beneath the Dunedin Volcanic Group, New Zealand, and their implications for intraplate alkaline magma sources

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