¹⁸²W evidence for core-mantle interaction in the source of mantle plumes

H. Rizo¹,

¹Department of Earth Sciences, Carleton University, Ottawa-Carleton Geoscience Centre, Ottawa, ON, K1S 5B6, Canada

D. Andrault²,

²Laboratoire Magmas et Volcans, Université Clermont-Auvergne, CNRS, IRD, OPGC, Clermont-Ferrand, France

N.R. Bennett³,

³Department of Earth and Planetary Sciences, University of California, Davis, CA 95616, USA

M. Humayun⁴,

⁴Department of Earth, Ocean and Atmospheric Science, and National High Magnetic Field Laboratory, Florida State University, Tallahassee, FL 32310, USA

A. Brandon⁵,

⁵Department of Earth and Atmospheric Sciences, University of Houston, Houston, TX 77204, USA

I. Vlastelic²,

²Laboratoire Magmas et Volcans, Université Clermont-Auvergne, CNRS, IRD, OPGC, Clermont-Ferrand, France

B. Moine⁶,

⁶Université Lyon, UJM Saint-Etienne, UCA, IRD, CNRS, Laboratoire Magmas et Volcans UMR 6524, Saint Etienne, France

A. Poirier⁷,

⁷Département des Sciences de la Terre et de l’atmosphère, Geotop-Université du Québec à Montréal, Montreal, QC, H2X 3Y7, Canada

M.A. Bouhifd²,

²Laboratoire Magmas et Volcans, Université Clermont-Auvergne, CNRS, IRD, OPGC, Clermont-Ferrand, France

D.T. Murphy⁸

⁸Queensland University of Technology, Brisbane, Queensland, Australia

Affiliations | Corresponding Author | Cite as | Funding information

Geochemical Perspectives Letters v11 | doi: 10.7185/geochemlet.1917
Received 1 April 2019 | Accepted 17 May 2019 | Published 20 June 2019

Published by the European Association of Geochemistry
under Creative Commons License CC BY-NC-ND 4.0

Keywords: geochemical evolution of the Earth's mantle, core-mantle chemical interaction, 182W, 142Nd



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Abstract

Abstract | Letter | Acknowledgements | References | Supplementary Information

Tungsten isotopes are the ideal tracers of core-mantle chemical interaction. Given that W is moderately siderophile, it preferentially partitioned into the Earth’s core during its segregation, leaving the mantle depleted in this element. In contrast, Hf is lithophile, and its short-lived radioactive isotope ¹⁸²Hf decayed entirely to ¹⁸²W in the mantle after metal-silicate segregation. Therefore, the ¹⁸²W isotopic composition of the Earth’s mantle and its core are expected to differ by about 200 ppm. Here, we report new high precision W isotope data for mantle-derived rock samples from the Paleoarchean Pilbara Craton, and the Réunion Island and the Kerguelen Archipelago hotspots. Together with other available data, they reveal a temporal shift in the ¹⁸²W isotopic composition of the mantle that is best explained by core-mantle chemical interaction. Core-mantle exchange might be facilitated by diffusive isotope exchange at the core-mantle boundary, or the exsolution of W-rich, Si-Mg-Fe oxides from the core into the mantle. Tungsten-182 isotope compositions of mantle-derived magmas are similar from 4.3 to 2.7 Ga and decrease afterwards. This change could be related to the onset of the crystallisation of the inner core or to the initiation of post-Archean deep slab subduction that more efficiently mixed the mantle.

Figures and Tables

Table 1 Tungsten isotope results for rock samples from the Pilbara Craton, the Kerguelen Archipelago, Réunion Island and the Hawaiian basalt BHVO-2.	Figure 1 ¹⁸²W/¹⁸⁴W data obtained in this study shown as µ¹⁸²W values. Open symbols are individual analysis of samples and filled symbols show the average of the different duplicates. Errors on individual measurements shown are 2 standard error (2 s.e.) and propagated uncertainties are shown for averages. The shaded area represents the reproducibility obtained (2 s.d.) on repeated measurements of the Alfa Aesar W standard.	Figure 2 Compilation of all existing ¹⁸²W/¹⁸⁴W data shown as µ¹⁸²W values. Hadean and Archean mantle-derived rocks are organised in order of their age, with the oldest at the top and the youngest at the bottom. Shaded areas show the average µ¹⁸²W values ± 2 s.d. for Hadean-Archean and OIB samples. OIB: Ocean Island Basalts. MORB: Mid-Ocean Ridge Basalts. Data sources: Willbold et al., 2011, 2015; Touboul et al., 2012, 2014; Liu et al., 2016; Puchtel et al., 2016, 2018; Rizo et al., 2016a,b; Dale et al., 2017; Mundl et al., 2017; Kruijer and Kleine, 2018; Mei et al., 2018; Reimink et al., 2018; and this study.	Figure 3 Schematic cartoon showing possible processes for core-mantle chemical interaction.
Table 1	Figure 1	Figure 2	Figure 3

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Letter

Abstract | Letter | Acknowledgements | References | Supplementary Information

Deep-rooted upwelling mantle plumes are potential candidates for carrying geochemical evidence of chemical interaction between the liquid outer core and the base of the mantle. Ocean island basalts (OIB), erupted at hotspots, are the surface expression of these mantle plumes. While the He and Os isotope compositions and Fe/Mn ratios of these magmas have been interpreted as possible evidence for core-mantle exchange (e.g., Walker et al., 1995

Walker, R.J., Morgan, J.W., Horan, M.F. (1995) Osmium-187 enrichment in some plumes: evidence for core-mantle interaction?. Science 269, 819-822.

; Brandon et al., 1998

Brandon, A.D., Walker, R.J., Morgan, J.W., Norman, M.D., Prichard, H.M. (1998) Coupled ¹⁸⁶Os and ¹⁸⁷Os evidence for core-mantle interaction. Science 280, 1570-1573.

; Porcelli and Halliday, 2001

Porcelli, D., Halliday, A.N. (2001) The core as a possible source of mantle helium. Earth and Planetary Science Letters 192, 45-56.

; Humayun et al., 2004

Humayun, M., Qin, L., Norman, M.D. (2004) Geochemical evidence for excess iron in the mantle beneath Hawaii. Science 306, 91-94.

; Bouhifd et al., 2013

Bouhifd, M.A., Jephcoat, A.P., Heber, V.S., Kelley, S.P. (2013) Helium in an early Earth’s core. Nature Geoscience 6, 982-986.

), other interpretations have also been invoked (e.g., Sobolev et al., 2007

Sobolev, A.V., Hofmann, A.W., Kuzmin, D.V., Yaxley, G.M., Arndt, N.T., Chung, S.L., Danyushevsky, L.V., Elliott, T., Frey, F.A., Garcia, M.O., Gurenko, A.A., Kamenetsky, V.S., Kerr, A.C., Krivolutskaya, N.A., Matvienkov, V.V., Nikogosian, I.K., Rocholl, A., Sigurdsson, I.A., Sushchevskaya, N.M., Teklay, M. (2007) The amount of recycled crust in sources of mantle-derived melts. Science 316, 412-417.

; Lassiter, 2006

Lassiter, J.C. (2006) Constraints on the coupled thermal evolution of the Earth's core and mantle, the age of the inner core, and the origin of the ¹⁸⁶Os/¹⁸⁸Os “core signal” in plume-derived lavas. Earth and Planetary Science Letters 250, 306-317.

; Luguet et al., 2008

Luguet, A., Pearson, D.G., Nowell, G.M., Dreher, S.T., Coggon, J.A., Spetsius, Z.V., Parman, S. W. (2008) Enriched Pt-Re-Os isotope systematics in plume lavas explained by metasomatic sulfides. Science 319, 453-456.

).

Strong evidence for core-mantle interaction may come from the short-lived ¹⁸²Hf-¹⁸²W system. With a half-life of 8.9 Ma (Vockenhuber et al., 2004

Vockenhuber, C., Oberli, F., Bichler, M., Ahmad, I., Quitté, G., Meier, M., Halliday, A.N., Lee, D.-C., Kutschera, W., Steier, P., Gehrke, R.J., Helmer, R.G. (2004) New Half-Life Measurement of Hf-182: Improved Chronometer for the Early Solar System. Physical Review Letters 93, 172501.

), ¹⁸²Hf decayed into ¹⁸²W during the first ~50 Myr of the solar system’s history. Since Hf is a lithophile element, it is concentrated in the silicate portion of the Earth. In contrast, W partitions preferentially into metal, and mass balance calculations suggest that ~90 % of the Earth’s W resides in the core (McDonough, 2003

McDonough, W.F. (2003) Compositional model for the Earth's core. Treatise on geochemistry 2, 568.

). The difference in the W isotopic composition of the Earth’s mantle and chondritic meteorites implies that the W-rich core has a ¹⁸²W/¹⁸⁴W ratio ~200 ppm lower than the mantle (e.g., Kleine et al., 2009

Kleine, T., Touboul, M., Bourdon, B., Nimmo, F., Mezger, K., Palme, H., Jacobsen, S.B., Yin, Q.-Z., Halliday, A.N. (2009) Hf–W chronology of the accretion and early evolution of asteroids and terrestrial planets. Geochimica et Cosmochimica Acta 73, 5150-5188.

). Therefore, chemical exchange between the core and the source of mantle plumes could be detectable in the ¹⁸²W/¹⁸⁴W ratio of OIB.

The samples studied here are plume-related volcanic rocks from the Réunion Island and the Kerguelen Archipelago hotspots, the certified reference material Hawaiian basalt BHVO-2, as well as samples from the ~3.475 Ga Mount Ada Basalts of the Pilbara Craton (samples and analytical methods are described in the Supplementary Information). The ¹⁸²W isotope compositions of these samples are presented as µ¹⁸²W values in Table 1 and Figure 1, which are deviations in ppm from the W isotopic composition of the terrestrial standard (assumed µ¹⁸²W = 0). All plume-related samples analysed here yield negative µ¹⁸²W values ranging from -5.2 ± 3.7 to -20.2 ± 5.1, including BHVO-2, which yields an average µ¹⁸²W of -6.6 ± 1.9, consistent with previous reports (Willbold et al., 2011

Willbold, M., Elliott, T., Moorbath, S. (2011) The tungsten isotopic composition of the Earth’s mantle before the terminal bombardment. Nature 477, 195.

; Mundl et al., 2017

Mundl, A., Touboul, M., Jackson, M.G., Day, J.M., Kurz, M.D., Lekic, V., Helz, R.T., Walker, R.J. (2017) Tungsten-182 heterogeneity in modern ocean island basalts. Science 356, 66-69.

; Kruijer and Kleine, 2018

Kruijer, T.S., Kleine, T. (2018) No ¹⁸²W excess in the Ontong Java Plateau source. Chemical Geology 485, 24-31.

; Mei et al., 2018

Mei, Q.F., Yang, J.H., Yang, Y.H. (2018) An improved extraction chromatographic purification of tungsten from a silicate matrix for high precision isotopic measurements using MC-ICPMS. Journal of Analytical Atomic Spectrometry 33, 569-577.

). In contrast, the ~3.475 Ga Mt. Ada Basalts samples yield positive µ¹⁸²W values of +15.3 ± 4.6 and +13.1 ± 4.1, in the same range as most Hadean and Eoarchean mantle-derived rocks. Deviations measured in µ¹⁸²W are not associated with deviations in µ¹⁸³W, confirming that ¹⁸²W variability is not the result of nuclear field shift effects (Figs. S-1 and S-2).

Table 1 Tungsten isotope results for rock samples from the Pilbara Craton, the Kerguelen Archipelago, Réunion Island and the Hawaiian basalt BHVO-2.

Location	Sample	µ¹⁸²W	µ¹⁸³W
Réunion Island	REU 1001-053	-19.0 ± 4.0	-3.3 ± 3.5
	REU 1001-053 duplicate	-12.4 ± 5.0	-1.6 ± 4.0
	REU 1001-053 average	-15.7 ± 3.2	-2.4 ± 2.7

	REU 1406-24.9a	-20.2 ± 5.1	-5.8 ± 4.7

	REU 863-204	-8.7 ± 3.8	0.7 ± 3.3
	REU 863-204 duplicate	-9.2 ± 4.0	-0.8 ± 3.4
	REU 863-204 average	-8.9 ± 2.8	-0.1 ± 2.4

	REU 0609-131	-7.6 ± 5.3	0.4 ± 4.7
	REU 0609-131 duplicate	-8.8 ± 3.9	4.0 ± 3.2
	REU 0609-131 average	-8.2 ± 3.3	2.2 ± 2.9
Kerguelen Plateau	TC0603	-16.5 ± 8.5	-3.1 ± 5.8
	TC0603 duplicate	-7.3 ± 4.0	2.1 ± 3.4
	TC0603 average	-11.9 ± 4.7	-0.5 ± 3.3

	CT02-358	-9.4 ± 7.4	-2.8 ± 7.2
	CT02-358 duplicate	-7.4 ± 3.0	1.9 ± 2.6
	CT02-358 average	-8.4 ± 4.0	-0.4 ± 3.8

	CT02-548	-15.2 ± 4.6	1.1 ± 3.7
Hawaii	BHVO-2	-7.2 ± 4.5	-0.9 ± 3.9
	BHVO-2 duplicate	-5.9 ± 4.5	4.3 ± 3.9
	BHVO-2 average	-6.6 ± 3.2	1.7 ± 2.8
Pilbara Craton	AH-25	15.3 ± 4.6	2.4 ± 3.7

	AH-26	13.1 ± 4.1	5.2 ± 3.5

µ^XW values (µ^XW = ([(^XW/¹⁸⁴W)sample/(^XW/¹⁸⁴W)standard]-1) x 10⁶) are relative deviations of the W isotope composition of the samples from the Alfa Aesar W terrestrial standard in ppm. The standard was measured repeatedly between samples and yields a reproducibility on the ¹⁸²W/¹⁸⁴W ratio of 4.7 ppm (2 s.d., n = 11). Duplicates are measurements from different rock digestions. Errors on individual measurements are 2 standard error (2 s.e.) and averages show the propagated uncertainties on the average of multiple duplicates.

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**Figure 1** ¹⁸²W/¹⁸⁴W data obtained in this study shown as µ¹⁸²W values. Open symbols are individual analysis of samples and filled symbols show the average of the different duplicates. Errors on individual measurements shown are 2 standard error (2 s.e.) and propagated uncertainties are shown for averages. The shaded area represents the reproducibility obtained (2 s.d.) on repeated measurements of the Alfa Aesar W standard.

Coupled with other high precision W isotope studies of mantle-derived rocks, the data reveal that the ¹⁸²W isotopic composition in the Hadean-Archaean mantle was different from the modern mantle (Fig. 2). With the exception of the ~3.55 Ga Schapenburg komatiites, Hadean to Archean volcanism sampled a mantle characterised by ¹⁸²W excesses of +5 to +20 ppm. In contrast, the mantle accessed by modern mantle-plume magmatism is characterised by ¹⁸²W anomalies from +5 to -20 ppm. The lavas from the Canary Islands are the only OIB to display resolvable ¹⁸²W excesses, however, this hotspot seems to originate at shallower depths (King and Ritsema, 2000

King, S.D., Ritsema, J. (2000) African hot spot volcanism: small-scale convection in the upper mantle beneath cratons. Science 290, 1137-1140.

; Courtillot et al., 2003

Courtillot, V., Davaille, A., Besse, J., Stock, J. (2003) Three distinct types of hotspots in the Earth’s mantle. Earth and Planetary Science Letters 205, 295-308.

) and various geochemical tracers suggest these magmas were contaminated by the ancient continental root (e.g., Thirlwall et al., 1997

Thirlwall, M.F., Jenkins, C., Vroon, P.Z., Mattey, D.P. (1997) Crustal interaction during construction of ocean islands: Pb-Sr-Nd-O isotope geochemistry of the shield basalts of Gran Canaria, Canary Islands. Chemical Geology 135, 233-262.

**Figure 2** Compilation of all existing ¹⁸²W/¹⁸⁴W data shown as µ¹⁸²W values. Hadean and Archean mantle-derived rocks are organised in order of their age, with the oldest at the top and the youngest at the bottom. Shaded areas show the average µ¹⁸²W values ± 2 s.d. for Hadean-Archean and OIB samples. OIB: Ocean Island Basalts. MORB: Mid-Ocean Ridge Basalts. Data sources: Willbold *et al.*, 2011
Willbold, M., Elliott, T., Moorbath, S. (2011) The tungsten isotopic composition of the Earth’s mantle before the terminal bombardment. *Nature* 477, 195.
, 2015
Willbold, M., Mojzsis, S.J., Chen, H.W., Elliott, T. (2015) Tungsten isotope composition of the Acasta Gneiss Complex. *Earth and Planetary Science Letters* 419, 168-177.
; Touboul *et al.*, 2012
Touboul, M., Puchtel, I.S., Walker, R.J. (2012) ¹⁸²W evidence for long-term preservation of early mantle differentiation products. *Science* 335, 1065-1069.
, 2014
Touboul, M., Liu, J., O'Neil, J., Puchtel, I.S., Walker, R.J. (2014) New insights into the Hadean mantle revealed by ¹⁸²W and highly siderophile element abundances of supracrustal rocks from the Nuvvuagittuq Greenstone Belt, Quebec, Canada. *Chemical Geology* 383, 63-75.
; Liu *et al.*, 2016
Liu, J., Touboul, M., Ishikawa, A., Walker, R.J., Pearson, D.G. (2016) Widespread tungsten isotope anomalies and W mobility in crustal and mantle rocks of the Eoarchean Saglek Block, northern Labrador, Canada: Implications for early Earth processes and W recycling. *Earth and Planetary Science Letters* 448, 13-23.
; Puchtel *et al.*, 2016
Puchtel, I.S., Blichert‐Toft, J., Touboul, M., Horan, M.F., Walker, R.J. (2016) The coupled ¹⁸²W-¹⁴²Nd record of early terrestrial mantle differentiation. *Geochemistry, Geophysics, Geosystems* 17, 2168-2193.
, 2018
Puchtel, I.S., Blichert-Toft, J., Touboul, M., Walker, R.J. (2018) ¹⁸²W and HSE constraints from 2.7 Ga komatiites on the heterogeneous nature of the Archean mantle. *Geochimica et Cosmochimica Acta* 228, 1-26.
; Rizo *et al.*, 2016a
Rizo, H., Walker, R.J., Carlson, R.W., Horan, M.F., Mukhopadhyay, S., Manthos, V., Francis, D., Jackson, M.G. (2016a) Preservation of Earth-forming events in the tungsten isotopic composition of modern flood basalts. *Science* 352, 809-812.
,b
Rizo, H., Walker, R.J., Carlson, R.W., Touboul, M., Horan, M.F., Puchtel, I.S., Boyet, M., Rosing, M.T. (2016b) Early Earth differentiation investigated through ¹⁴²Nd, ¹⁸²W, and highly siderophile element abundances in samples from Isua, Greenland. *Geochimica et Cosmochimica Acta* 175, 319-336.
; Dale *et al.*, 2017
Dale, C.W., Kruijer, T.S., Burton, K.W. (2017) Highly siderophile element and ¹⁸²W evidence for a partial late veneer in the source of 3.8 Ga rocks from Isua, Greenland. *Earth and Planetary Science Letters* 458, 394-404.
; Mundl *et al.*, 2017
Mundl, A., Touboul, M., Jackson, M.G., Day, J.M., Kurz, M.D., Lekic, V., Helz, R.T., Walker, R.J. (2017) Tungsten-182 heterogeneity in modern ocean island basalts. *Science* 356, 66-69.
; Kruijer and Kleine, 2018
Kruijer, T.S., Kleine, T. (2018) No ¹⁸²W excess in the Ontong Java Plateau source. *Chemical Geology* 485, 24-31.
; Mei *et al.*, 2018
Mei, Q.F., Yang, J.H., Yang, Y.H. (2018) An improved extraction chromatographic purification of tungsten from a silicate matrix for high precision isotopic measurements using MC-ICPMS. *Journal of Analytical Atomic Spectrometry* 33, 569-577.
; Reimink *et al.*, 2018
Reimink, J.R., Chacko, T., Carlson, R.W., Shirey, S.B., Liu, J., Stern, R.A., Bauer, A.M., Pearson, D.G., Heaman, L.M. (2018) Petrogenesis and tectonics of the Acasta Gneiss Complex derived from integrated petrology and ¹⁴²Nd and ¹⁸²W extinct nuclide-geochemistry. *Earth and Planetary Science Letters* 494, 12-22.
; and this study.

Several processes have been proposed to explain the cause of ¹⁸²W variability. None of these processes, however, seems to explain all geochemical observations satisfactorily. For example, excesses in ¹⁸²W observed in ancient rock samples could arise if they derived from mantle sources that remained partially isolated from the incorporation, after core formation, of meteoritic material (e.g., Willbold et al., 2011

Willbold, M., Elliott, T., Moorbath, S. (2011) The tungsten isotopic composition of the Earth’s mantle before the terminal bombardment. Nature 477, 195.

). This late-accreted material is assumed to possess µ¹⁸²W ~ -200, and its gradual homogenisation into the mantle would have decreased its µ¹⁸²W with time. Late accretion of ~0.5 wt. % of the Earth has also been invoked to explain the higher than expected highly siderophile element (HSE; Re, Os, Ir, Ru, Pt, Pd) abundances in Earth’s mantle (e.g., Chou et al., 1978

Chou, C.L. (1978) Fractionation of siderophile elements in the Earth's upper mantle. Proceedings of the 9th Lunar and Planetary Science Conference 1, 219-230.

; Walker, 2009

Walker, R.J. (2009) Highly siderophile elements in the Earth, Moon and Mars: update and implications for planetary accretion and differentiation. Chemie der Erde-Geochemistry 69, 101-125.

). Therefore, variability of ¹⁸²W is expected to correlate with HSE source abundances. Yet, it rarely does, and the HSE depleted Schapenburg samples even indicate the opposite relationship (Puchtel et al., 2016

Puchtel, I.S., Blichert‐Toft, J., Touboul, M., Horan, M.F., Walker, R.J. (2016) The coupled ¹⁸²W-¹⁴²Nd record of early terrestrial mantle differentiation. Geochemistry, Geophysics, Geosystems 17, 2168-2193.

). Estimating HSE abundances of mantle sources is, however, complicated since these elements are controlled by sulphides, whose partial melting behaviour is very complex.

Another proposed process is that early (<50 Ma) silicate differentiation, following crystallisation of a magma ocean, could have also created ¹⁸²W variability. Since W is more incompatible than Hf (Shearer and Righter, 2003

Shearer, C.K., Righter, K. (2003) Behavior of tungsten and hafnium in silicates: a crystal chemical basis for understanding the early evolution of the terrestrial planets. Geophysical Research Letters 30, 7-1.

), early differentiated reservoirs will be characterised by fractionated Hf/W ratios and develop excesses and deficits in ¹⁸²W. Silicate differentiation in the first 50 Ma of Earth’s history should have also affected the short-lived ¹⁴⁶Sm-¹⁴²Nd isotope system (t_1/2= 103 Ma; Marks et al., 2014

Marks, N.E., Borg, L.E., Hutcheon, I.D., Jacobsen, B., Clayton, R.N. (2014) Samarium–neodymium chronology and rubidium–strontium systematics of an Allende calcium–aluminum-rich inclusion with implications for ¹⁴⁶Sm half-life. Earth and Planetary Science Letters 405, 15-24.

). Coupled ¹⁴²Nd and ¹⁸²W anomalies in the ancient rock record, however, are not ubiquitous and most modern mantle rocks measured so far exhibit ¹⁴²Nd variations that deviate by less than 5 ppm from the terrestrial standard (Fig. S-3).

While the scenarios discussed above might explain some of the ¹⁸²W anomalies detected in the rock record, the temporal shift observed in the W isotopic composition of the mantle seems to reflect one predominating process. Chemical interaction between the core and the mantle sources of plumes could be such a process. Core-mantle interaction does not affect lithophile elements such as Nd, and is thus compatible with the observed lack of coupling between ¹⁸²W and ¹⁴²Nd. Furthermore, the correlations between ¹⁸²W and ³He/⁴He ratios (Mundl et al., 2017

Mundl, A., Touboul, M., Jackson, M.G., Day, J.M., Kurz, M.D., Lekic, V., Helz, R.T., Walker, R.J. (2017) Tungsten-182 heterogeneity in modern ocean island basalts. Science 356, 66-69.

) and Fe/Mn ratios (Fig. S-4) could corroborate this process, since both He and Fe/Mn have also been proposed as tracers of core-mantle interaction (Porcelli and Halliday, 2001

Porcelli, D., Halliday, A.N. (2001) The core as a possible source of mantle helium. Earth and Planetary Science Letters 192, 45-56.

; Humayun et al., 2004

Humayun, M., Qin, L., Norman, M.D. (2004) Geochemical evidence for excess iron in the mantle beneath Hawaii. Science 306, 91-94.

; Bouhifd et al., 2013

Bouhifd, M.A., Jephcoat, A.P., Heber, V.S., Kelley, S.P. (2013) Helium in an early Earth’s core. Nature Geoscience 6, 982-986.

). In this scenario, the Earth’s mantle, initially characterised by a maximum µ¹⁸²W value of +20, was subject to core addition that created domains with µ¹⁸²W values as low as -20. The most negative µ¹⁸²W values measured in OIB constrain the maximum core contribution to their sources to ~0.8 wt. %, calculated by mass balance assuming a core µ¹⁸²W value of -200 (Kleine et al., 2009

) and W concentration of ~500 ppb (McDonough, 2003

McDonough, W.F. (2003) Compositional model for the Earth's core. Treatise on geochemistry 2, 568.

).

Diffusive isotope exchange of W at the core-mantle boundary (CMB) is one of the plausible mechanisms of core-mantle interaction (Fig. 3). At CMB conditions, grain boundary diffusion experiments indicate W can diffuse over distances of 1-10 km in the mantle over 100 Myr (Hayden and Watson, 2007

Hayden, L.A., Watson, E.B. (2007) A diffusion mechanism for core–mantle interaction. Nature 450, 709.

) and even higher diffusion rates may arise from the presence of partially molten silicates at the CMB (e.g., Andrault et al., 2014

Andrault, D., Pesce, G., Bouhifd, M.A., Bolfan-Casanova, N., Hénot, J.M., Mezouar, M. (2014) Melting of subducted basalt at the core-mantle boundary. Science 344, 892-895.

; Yuan and Romanowicz, 2017

Yuan, K., Romanowicz, B. (2017) Seismic evidence for partial melting at the root of major hot spot plumes. Science 357, 393-397.

). Hayden and Watson (2007)

Hayden, L.A., Watson, E.B. (2007) A diffusion mechanism for core–mantle interaction. Nature 450, 709.

also determined the grain boundary diffusivity of the HSE, and concluded that these elements are also susceptible to ‘leaking’ from the core over geological timescales. The high concentrations of HSE in the core relative to the mantle mean that even a small flux of HSEs from the core should result in coupling between µ¹⁸²W and HSE abundances in mantle-derived rocks. As discussed above, mantle-derived rocks with negative µ¹⁸²W values do not possess HSE enrichments, perhaps suggesting that this is not the primary mechanism of core-mantle interaction. However, relating HSE concentrations in mantle-derived rocks to the composition of their source regions is challenging and means we cannot rule out diffusion as a viable mechanism.

**Figure 3** Schematic cartoon showing possible processes for core-mantle chemical interaction.

Core-mantle interaction could be also a consequence of Si-Mg-Fe oxide exsolutions from the core (Badro et al., 2016

Badro, J., Siebert, J., Nimmo, F. (2016) An early geodynamo driven by exsolution of mantle components from Earth’s core. Nature 536, 326.

; O’Rourke and Stevenson, 2016

O’Rourke, J.G., Stevenson, D.J. (2016) Powering Earth’s dynamo with magnesium precipitation from the core. Nature 529, 387.

; Hirose et al., 2017

Hirose, K., Morard, G., Sinmyo, R., Umemoto, K., Hernlund, J., Helffrich, G., Labrosse, S. (2017) Crystallization of silicon dioxide and compositional evolution of the Earth’s core. Nature 543, 99.

) (Fig. 3). Our experimental results show that these oxides can efficiently incorporate W in their structure without the accompanying HSE (Supplementary Information; Figs. S-5 and S-6). These exsolutions are expected to form by simple secular core cooling, since the solubility of oxides in liquid iron decreases with decreasing temperature (Badro et al., 2016

Badro, J., Siebert, J., Nimmo, F. (2016) An early geodynamo driven by exsolution of mantle components from Earth’s core. Nature 536, 326.

; O’Rourke and Stevenson, 2016

O’Rourke, J.G., Stevenson, D.J. (2016) Powering Earth’s dynamo with magnesium precipitation from the core. Nature 529, 387.

; Hirose et al., 2017

). Additional to core cooling, the crystallisation of the inner core likely led to higher oxygen concentrations in the outer liquid core and increased Si-Mg-Fe oxide precipitation, since oxygen is not easily incorporated into solid iron (Alfè et al., 2002

Alfè, D., Price, G.D., Gillan, M.J. (2002) Iron under Earth’s core conditions: Liquid-state thermodynamics and high-pressure melting curve from ab initio calculations. Physical Review B 65, 16511.

). More oxidising conditions in the outer core decreases the affinity of W for the liquid metal (Righter and Ghiorso, 2012

Righter, K., Ghiorso, M.S. (2012) Redox systematics of a magma ocean with variable pressure-temperature gradients and composition. Proceedings of the National Academy of Sciences 109, 11955-11960.

; Wade et al., 2012

Wade, J., Wood, B.J., Tuff, J. (2012) Metal–silicate partitioning of Mo and W at high pressures and temperatures: evidence for late accretion of sulphur to the Earth. Geochimica et Cosmochimica Acta 85, 58-74.

), inducing the extraction of W from the core and its incorporation into the mantle.

Regardless of the exact mechanism of core-mantle interaction, a key observation to consider is that the mantle between 4.3 Ga and 2.7 Ga seems to be characterised by constant µ¹⁸²W values, which have decreased in the modern mantle (Fig. 2). This broad distinction in µ¹⁸²W vs. age could imply a change in mantle dynamics after the Archean. Slab subduction of oxidised material into the deep mantle might have induced W disequilibrium at the CMB by increasing its fO₂ (van der Hilst and Kárason, 1999

van der Hilst, R.D., Kárason, H. (1999) Compositional heterogeneity in the bottom 1000 kilometers of Earth's mantle: toward a hybrid convection model. Science 283, 1885-1888.

). Since W adopts a high valence (4+ to 6+) in silicates, increasing the fO₂ at the CMB decreases its siderophile behaviour (e.g., Righter and Ghiorso, 2012

Righter, K., Ghiorso, M.S. (2012) Redox systematics of a magma ocean with variable pressure-temperature gradients and composition. Proceedings of the National Academy of Sciences 109, 11955-11960.

; Wade et al., 2012

), favouring its extraction from the core and incorporation in the lower mantle. Deep slab subduction might have also played a role in scavenging material from the CMB. Alternatively, the change of µ¹⁸²W values in the post-Archaean mantle could be related to the crystallisation of the inner core. Large experimental uncertainties on thermal conductivity values of liquid iron in the outer core limit our understanding of inner core crystallisation. If changes in the µ¹⁸²W signature of deep mantle plumes are related to the onset of inner core segregation, µ¹⁸²W could be used as an alternative tool to study this process.

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Acknowledgements

Abstract | Letter | Acknowledgements | References | Supplementary Information

This manuscript was improved after insightful comments from G. Pearson and four anonymous reviewers and the editor, A. Luguet. We appreciate helpful discussions with R.W. Carlson, R. Walker and J. O’Neil, and discussions related to analytical protocols with G. Quitté, G. Archer and J. Blenkinsop. We thank L. Bouvier for her participation in the beginning of this project, and S. Zhang for assistance with TIMS, and N. DeSilva and S. Mohanty for assistance with ICP-MS facilities. We also thank the Geological Survey of Western Australia and R. Hepple for assistance with collection of the Pilbara Craton samples. This research was supported by a Natural Sciences and Engineering Research Council of Canada (NSERC) Discovery grant to H. Rizo (RGPIN-2015-03982), and by the Fonds de Recherche Nature et Technologies (FRQNT) start up programme for new university researchers.

Editor: Ambre Luguet

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References

Abstract | Letter | Acknowledgements | References | Supplementary Information

Show in context

Additional to core cooling, the crystallisation of the inner core likely led to higher oxygen concentrations in the outer liquid core and increased Si-Mg-Fe oxide precipitation, since oxygen is not easily incorporated into solid iron (Alfè et al., 2002).
View in article

Andrault, D., Pesce, G., Bouhifd, M.A., Bolfan-Casanova, N., Hénot, J.M., Mezouar, M. (2014) Melting of subducted basalt at the core-mantle boundary. Science 344, 892-895.

Show in context

Badro, J., Siebert, J., Nimmo, F. (2016) An early geodynamo driven by exsolution of mantle components from Earth’s core. Nature 536, 326.

Show in context

Core-mantle interaction could be also a consequence of Si-Mg-Fe oxide exsolutions from the core (Badro et al., 2016; O’Rourke and Stevenson, 2016; Hirose et al., 2017) (Fig. 3).
View in article
These exsolutions are expected to form by simple secular core cooling, since the solubility of oxides in liquid iron decreases with decreasing temperature (Badro et al., 2016; O’Rourke and Stevenson, 2016; Hirose et al., 2017).
View in article

Brandon, A.D., Walker, R.J., Morgan, J.W., Norman, M.D., Prichard, H.M. (1998) Coupled ¹⁸⁶Os and ¹⁸⁷Os evidence for core-mantle interaction. Science 280, 1570-1573.

Show in context

Bouhifd, M.A., Jephcoat, A.P., Heber, V.S., Kelley, S.P. (2013) Helium in an early Earth’s core. Nature Geoscience 6, 982-986.

Show in context

While the He and Os isotope compositions and Fe/Mn ratios of these magmas have been interpreted as possible evidence for core-mantle exchange (e.g., Walker et al., 1995; Brandon et al., 1998; Porcelli and Halliday, 2001; Humayun et al., 2004; Bouhifd et al., 2013), other interpretations have also been invoked (e.g., Sobolev et al., 2007; Lassiter, 2006; Luguet et al., 2008).
View in article
Furthermore, the correlations between ¹⁸²W and ³He/⁴He ratios (Mundl et al., 2017) and Fe/Mn ratios (Fig. S-4) could corroborate this process, since both He and Fe/Mn have also been proposed as tracers of core-mantle interaction (Porcelli and Halliday, 2001; Humayun et al., 2004; Bouhifd et al., 2013).
View in article

Chou, C.L. (1978) Fractionation of siderophile elements in the Earth's upper mantle. Proceedings of the 9th Lunar and Planetary Science Conference 1, 219-230.

Show in context

Late accretion of ~0.5 wt. % of the Earth has also been invoked to explain the higher than expected highly siderophile element (HSE; Re, Os, Ir, Ru, Pt, Pd) abundances in Earth’s mantle (e.g., Chou et al., 1978; Walker, 2009).
View in article

Courtillot, V., Davaille, A., Besse, J., Stock, J. (2003) Three distinct types of hotspots in the Earth’s mantle. Earth and Planetary Science Letters 205, 295-308.

Show in context

The lavas from the Canary Islands are the only OIB to display resolvable ¹⁸²W excesses, however, this hotspot seems to originate at shallower depths (King and Ritsema, 2000; Courtillot et al., 2003) and various geochemical tracers suggest these magmas were contaminated by the ancient continental root (e.g., Thirlwall et al., 1997).
View in article

Dale, C.W., Kruijer, T.S., Burton, K.W. (2017) Highly siderophile element and ¹⁸²W evidence for a partial late veneer in the source of 3.8 Ga rocks from Isua, Greenland. Earth and Planetary Science Letters 458, 394-404.

Show in context

Hayden, L.A., Watson, E.B. (2007) A diffusion mechanism for core–mantle interaction. Nature 450, 709.

Show in context

At CMB conditions, grain boundary diffusion experiments indicate W can diffuse over distances of 1-10 km in the mantle over 100 Myr (Hayden and Watson, 2007) and even higher diffusion rates may arise from the presence of partially molten silicates at the CMB (e.g., Andrault et al., 2014; Yuan and Romanowicz, 2017).
View in article
Hayden and Watson (2007) also determined the grain boundary diffusivity of the HSE, and concluded that these elements are also susceptible to ‘leaking’ from the core over geological timescales.
View in article

Show in context

Humayun, M., Qin, L., Norman, M.D. (2004) Geochemical evidence for excess iron in the mantle beneath Hawaii. Science 306, 91-94.

Show in context

The difference in the W isotopic composition of the Earth’s mantle and chondritic meteorites implies that the W-rich core has a ¹⁸²W/¹⁸⁴W ratio ~200 ppm lower than the mantle (e.g., Kleine et al., 2009).
View in article
The most negative µ¹⁸²W values measured in OIB constrain the maximum core contribution to their sources to ~0.8 wt. %, calculated by mass balance assuming a core µ¹⁸²W value of -200 (Kleine et al., 2009) and W concentration of ~500 ppb (McDonough, 2003).
View in article

King, S.D., Ritsema, J. (2000) African hot spot volcanism: small-scale convection in the upper mantle beneath cratons. Science 290, 1137-1140.

Show in context

Kruijer, T.S., Kleine, T. (2018) No ¹⁸²W excess in the Ontong Java Plateau source. Chemical Geology 485, 24-31.

Show in context

Liu, J., Touboul, M., Ishikawa, A., Walker, R.J., Pearson, D.G. (2016) Widespread tungsten isotope anomalies and W mobility in crustal and mantle rocks of the Eoarchean Saglek Block, northern Labrador, Canada: Implications for early Earth processes and W recycling. Earth and Planetary Science Letters 448, 13-23.

Show in context

Silicate differentiation in the first 50 Ma of Earth’s history should have also affected the short-lived ¹⁴⁶Sm-¹⁴²Nd isotope system (t_1/2 = 103 Ma; Marks et al., 2014).
View in article

McDonough, W.F. (2003) Compositional model for the Earth's core. Treatise on geochemistry 2, 568.

Show in context

In contrast, W partitions preferentially into metal, and mass balance calculations suggest that ~90 % of the Earth’s W resides in the core (McDonough, 2003).
View in article
The most negative µ¹⁸²W values measured in OIB constrain the maximum core contribution to their sources to ~0.8 wt. %, calculated by mass balance assuming a core µ¹⁸²W value of -200 (Kleine et al., 2009) and W concentration of ~500 ppb (McDonough, 2003).
View in article

Show in context

Mundl, A., Touboul, M., Jackson, M.G., Day, J.M., Kurz, M.D., Lekic, V., Helz, R.T., Walker, R.J. (2017) Tungsten-182 heterogeneity in modern ocean island basalts. Science 356, 66-69.

Show in context

All plume-related samples analysed here yield negative µ¹⁸²W values ranging from -5.2 ± 3.7 to -20.2 ± 5.1, including BHVO-2, which yields an average µ¹⁸²W of -6.6 ± 1.9, consistent with previous reports (Willbold et al., 2011; Mundl et al., 2017; Kruijer and Kleine, 2018; Mei et al., 2018).
View in article
Figure 2 [...] Data sources: Willbold et al., 2011, 2015; Touboul et al., 2012, 2014; Liu et al., 2016; Puchtel et al., 2016, 2018; Rizo et al., 2016a,b; Dale et al., 2017; Mundl et al., 2017; Kruijer and Kleine, 2018; Mei et al., 2018; Reimink et al., 2018; and this study.
View in article
Furthermore, the correlations between ¹⁸²W and ³He/⁴He ratios (Mundl et al., 2017) and Fe/Mn ratios (Fig. S-4) could corroborate this process, since both He and Fe/Mn have also been proposed as tracers of core-mantle interaction (Porcelli and Halliday, 2001; Humayun et al., 2004; Bouhifd et al., 2013).
View in article

O’Rourke, J.G., Stevenson, D.J. (2016) Powering Earth’s dynamo with magnesium precipitation from the core. Nature 529, 387.

Show in context

Porcelli, D., Halliday, A.N. (2001) The core as a possible source of mantle helium. Earth and Planetary Science Letters 192, 45-56.

Show in context

Figure 2 [...] Data sources: Willbold et al., 2011, 2015; Touboul et al., 2012, 2014; Liu et al., 2016; Puchtel et al., 2016, 2018; Rizo et al., 2016a,b; Dale et al., 2017; Mundl et al., 2017; Kruijer and Kleine, 2018; Mei et al., 2018; Reimink et al., 2018; and this study.
View in article
Yet, it rarely does, and the HSE depleted Schapenburg samples even indicate the opposite relationship (Puchtel et al., 2016).
View in article

Puchtel, I.S., Blichert-Toft, J., Touboul, M., Walker, R.J. (2018) ¹⁸²W and HSE constraints from 2.7 Ga komatiites on the heterogeneous nature of the Archean mantle. Geochimica et Cosmochimica Acta 228, 1-26.

Show in context

Reimink, J.R., Chacko, T., Carlson, R.W., Shirey, S.B., Liu, J., Stern, R.A., Bauer, A.M., Pearson, D.G., Heaman, L.M. (2018) Petrogenesis and tectonics of the Acasta Gneiss Complex derived from integrated petrology and ¹⁴²Nd and ¹⁸²W extinct nuclide-geochemistry. Earth and Planetary Science Letters 494, 12-22.

Show in context

Righter, K., Ghiorso, M.S. (2012) Redox systematics of a magma ocean with variable pressure-temperature gradients and composition. Proceedings of the National Academy of Sciences 109, 11955-11960.

Show in context

More oxidising conditions in the outer core decreases the affinity of W for the liquid metal (Righter and Ghiorso, 2012; Wade et al., 2012), inducing the extraction of W from the core and its incorporation into the mantle.
View in article
Since W adopts a high valence (4+ to 6+) in silicates, increasing the fO₂ at the CMB decreases its siderophile behaviour (e.g., Righter and Ghiorso, 2012; Wade et al., 2012), favouring its extraction from the core and incorporation in the lower mantle.
View in article

Rizo, H., Walker, R.J., Carlson, R.W., Horan, M.F., Mukhopadhyay, S., Manthos, V., Francis, D., Jackson, M.G. (2016a) Preservation of Earth-forming events in the tungsten isotopic composition of modern flood basalts. Science 352, 809-812.

Show in context

Rizo, H., Walker, R.J., Carlson, R.W., Touboul, M., Horan, M.F., Puchtel, I.S., Boyet, M., Rosing, M.T. (2016b) Early Earth differentiation investigated through ¹⁴²Nd, ¹⁸²W, and highly siderophile element abundances in samples from Isua, Greenland. Geochimica et Cosmochimica Acta 175, 319-336.

Show in context

Since W is more incompatible than Hf (Shearer and Righter, 2003), early differentiated reservoirs will be characterised by fractionated Hf/W ratios and develop excesses and deficits in ¹⁸²W.
View in article

Show in context

Touboul, M., Puchtel, I.S., Walker, R.J. (2012) ¹⁸²W evidence for long-term preservation of early mantle differentiation products. Science 335, 1065-1069.

Show in context

Touboul, M., Liu, J., O'Neil, J., Puchtel, I.S., Walker, R.J. (2014) New insights into the Hadean mantle revealed by ¹⁸²W and highly siderophile element abundances of supracrustal rocks from the Nuvvuagittuq Greenstone Belt, Quebec, Canada. Chemical Geology 383, 63-75.

Show in context

van der Hilst, R.D., Kárason, H. (1999) Compositional heterogeneity in the bottom 1000 kilometers of Earth's mantle: toward a hybrid convection model. Science 283, 1885-1888.

Show in context

Slab subduction of oxidised material into the deep mantle might have induced W disequilibrium at the CMB by increasing its fO₂ (van der Hilst and Kárason, 1999).
View in article

Show in context

With a half-life of 8.9 Ma (Vockenhuber et al., 2004), ¹⁸²Hf decayed into ¹⁸²W during the first ~50 Myr of the solar system’s history.
View in article

Walker, R.J. (2009) Highly siderophile elements in the Earth, Moon and Mars: update and implications for planetary accretion and differentiation. Chemie der Erde-Geochemistry 69, 101-125.

Show in context

Walker, R.J., Morgan, J.W., Horan, M.F. (1995) Osmium-187 enrichment in some plumes: evidence for core-mantle interaction?. Science 269, 819-822.

Show in context

Willbold, M., Elliott, T., Moorbath, S. (2011) The tungsten isotopic composition of the Earth’s mantle before the terminal bombardment. Nature 477, 195.

Show in context

All plume-related samples analysed here yield negative µ¹⁸²W values ranging from -5.2 ± 3.7 to -20.2 ± 5.1, including BHVO-2, which yields an average µ¹⁸²W of -6.6 ± 1.9, consistent with previous reports (Willbold et al., 2011; Mundl et al., 2017; Kruijer and Kleine, 2018; Mei et al., 2018).
View in article
Figure 2 [...] Data sources: Willbold et al., 2011, 2015; Touboul et al., 2012, 2014; Liu et al., 2016; Puchtel et al., 2016, 2018; Rizo et al., 2016a,b; Dale et al., 2017; Mundl et al., 2017; Kruijer and Kleine, 2018; Mei et al., 2018; Reimink et al., 2018; and this study.
View in article
For example, excesses in ¹⁸²W observed in ancient rock samples could arise if they derived from mantle sources that remained partially isolated from the incorporation, after core formation, of meteoritic material (e.g., Willbold et al., 2011).
View in article

Willbold, M., Mojzsis, S.J., Chen, H.W., Elliott, T. (2015) Tungsten isotope composition of the Acasta Gneiss Complex. Earth and Planetary Science Letters 419, 168-177.

Show in context

Yuan, K., Romanowicz, B. (2017) Seismic evidence for partial melting at the root of major hot spot plumes. Science 357, 393-397.

Show in context

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Supplementary Information

Abstract | Letter | Acknowledgements | References | Supplementary Information

The Supplementary Information includes:

1. Sample Description
2. Analytical Methods for W Concentrations and Isotope Measurements
3. Correlations Between ¹⁸²W and ³He/⁴He and Fe/Mn Ratios
4. Evidence for W solubility in Exsolved Oxides and Decoupling of W and HSE Abundances
Tables S-1 to S-4
Figures S-1 to S-6
Supplementary Information References

Download the Supplementary Information (PDF)

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Figures and Tables

Table 1 Tungsten isotope results for rock samples from the Pilbara Craton, the Kerguelen Archipelago, Réunion Island and the Hawaiian basalt BHVO-2.

Location	Sample	µ¹⁸²W	µ¹⁸³W
Réunion Island	REU 1001-053	-19.0 ± 4.0	-3.3 ± 3.5
	REU 1001-053 duplicate	-12.4 ± 5.0	-1.6 ± 4.0
	REU 1001-053 average	-15.7 ± 3.2	-2.4 ± 2.7

	REU 1406-24.9a	-20.2 ± 5.1	-5.8 ± 4.7

	REU 863-204	-8.7 ± 3.8	0.7 ± 3.3
	REU 863-204 duplicate	-9.2 ± 4.0	-0.8 ± 3.4
	REU 863-204 average	-8.9 ± 2.8	-0.1 ± 2.4

	REU 0609-131	-7.6 ± 5.3	0.4 ± 4.7
	REU 0609-131 duplicate	-8.8 ± 3.9	4.0 ± 3.2
	REU 0609-131 average	-8.2 ± 3.3	2.2 ± 2.9
Kerguelen Plateau	TC0603	-16.5 ± 8.5	-3.1 ± 5.8
	TC0603 duplicate	-7.3 ± 4.0	2.1 ± 3.4
	TC0603 average	-11.9 ± 4.7	-0.5 ± 3.3

	CT02-358	-9.4 ± 7.4	-2.8 ± 7.2
	CT02-358 duplicate	-7.4 ± 3.0	1.9 ± 2.6
	CT02-358 average	-8.4 ± 4.0	-0.4 ± 3.8

	CT02-548	-15.2 ± 4.6	1.1 ± 3.7
Hawaii	BHVO-2	-7.2 ± 4.5	-0.9 ± 3.9
	BHVO-2 duplicate	-5.9 ± 4.5	4.3 ± 3.9
	BHVO-2 average	-6.6 ± 3.2	1.7 ± 2.8
Pilbara Craton	AH-25	15.3 ± 4.6	2.4 ± 3.7

	AH-26	13.1 ± 4.1	5.2 ± 3.5