Unravelling lunar mantle source processes via the Ti isotope composition of lunar basalts

S. Kommescher¹,

¹Institut für Geologie und Mineralogie, Universität zu Köln, Germany

R.O.C. Fonseca^1,2,

¹Institut für Geologie und Mineralogie, Universität zu Köln, Germany
²Institut für Geologie, Mineralogie und Geophysik, Ruhr-Universität Bochum, Germany

F. Kurzweil¹,

¹Institut für Geologie und Mineralogie, Universität zu Köln, Germany

M.M. Thiemens^1,3,

¹Institut für Geologie und Mineralogie, Universität zu Köln, Germany
³G-TIME Laboratory, Université Libre de Bruxelles, Belgium

C. Münker¹,

¹Institut für Geologie und Mineralogie, Universität zu Köln, Germany

P. Sprung^1,4

¹Institut für Geologie und Mineralogie, Universität zu Köln, Germany
⁴Hot Laboratory Division (AHL), Paul Scherer Institut, Villigen, Switzerland

Affiliations | Corresponding Author | Cite as | Funding information

Geochemical Perspectives Letters v13 | doi: 10.7185/geochemlet.2007
Received 5 August 2019 | Accepted 24 January 2020 | Published 28 February 2020

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

Keywords: titanium isotopes, stable isotopes, Moon, Mare basalt



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Abstract

Formation and crystallisation of the Lunar Magma Ocean (LMO) was one of the most incisive events during the early evolution of the Moon. Lunar Magma Ocean solidification concluded with the coeval formation of K-, REE- and P-rich components (KREEP) and an ilmenite-bearing cumulate (IBC) layer. Gravitational overturn of the lunar mantle generated eruptions of basaltic rocks with variable Ti contents, of which their δ⁴⁹Ti variations may now reflect variable mixtures of ambient lunar mantle and the IBC. To better understand the processes generating the spectrum of lunar low-Ti and high-Ti basalts and the role of Ti-rich phases such as ilmenite, we determined the mass dependent Ti isotope composition of four KREEP-rich samples, 12 low-Ti, and eight high-Ti mare basalts by using a ⁴⁷Ti-⁴⁹Ti double spike. Our data reveal significant variations in δ⁴⁹Ti for KREEP-rich samples (+0.117 to +0.296 ‰) and intra-group variations in the mare basalts (-0.030 to +0.055 ‰ for low-Ti and +0.009 to +0.115 ‰ for high-Ti basalts). We modelled the δ⁴⁹Ti of KREEP using previously published HFSE data as well as the δ⁴⁹Ti evolution during fractional crystallisation of the LMO. Both approaches yield δ⁴⁹Ti_KREEP similar to measured values and are in excellent agreement with previous studies. The involvement of ilmenite in the petrogenesis of the lunar mare basalts is further evaluated by combining our results with element ratios of HFSE, U and Th, revealing that partial melting in an overturned lunar mantle and fractional crystallisation of ilmenite must be the main processes accounting for mass dependent Ti isotope variations in lunar basalts. Based on our results we can also exclude formation of high-Ti basalts by simple assimilation of ilmenite by ascending melts from the depleted lunar mantle. Rather, our data are in accord with melting of these basalts from a hybrid mantle source formed in the aftermath of gravitational lunar mantle overturn, which is in good agreement with previous Fe isotope data.

Figures and Tables

Figure 1 Measured Ti isotope compositions of lunar samples. All uncertainties unless stated otherwise are 95 % confidence interval (c.i.) of at least 6 measurements of the same aliquot. See main text and Supplementary Information for details. bce = breccia, ilm = ilmenite; QNB = quartz-normative basalt, olv = olivine, pgt = pigeonite.	Table 1 Summary of reference materials and measured samples. For reference materials, n gives the number of sequences in which the material has been measured at least 6 times. Abbreviations are the same as in Figure 1. Two aliquots of OL-Ti were ran through the chemical separation process and are given as OL-Ti (chemistry).	Figure 2 Plots of (a) δ⁴⁹Ti vs. MgO/TiO₂, (b) δ⁴⁹Ti vs. Ta/Hf and (c) δ⁴⁹Ti vs. U that can be used to discriminate between processes leading to variations in δ⁴⁹Ti. Symbols are the same as in Figure 1, black arrows indicate the direction in which a process would influence the values along y- and x-axes. Partial melting assumes the presence of ilmenite in the source, fractional crystallisation always implies fractional crystallisation of ilmenite. AFC implies the assimilation of an IBC component during ilmenite-free fractional crystallisation of a low-Ti magma. (b) The estimated Ta/Hf value of urKREEP is ~0.11 (Warren and Taylor, 2014). (c) Contamination by urKREEP (coloured arrow), would imply higher U contents (not observed). urKREEP is based on our first model (see Supplementary Information).
Figure 1	Table 1	Figure 2

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Introduction

It is widely accepted that the Moon formed as the result of an impact between one or more planetesimals and the proto-Earth (e.g., Asphaug, 2014

Asphaug, E. (2014) Impact Origin of the Moon? Annual Review of Earth and Planetary Sciences 42, 551–578.

). The last phases to solidify in the impact-induced Lunar Magma Ocean (LMO) were K-, REE-, and P-rich residual components (urKREEP) and complementarily an ilmenite-bearing cumulate (IBC; Warren and Wasson, 1979

Warren, P.H., Wasson, J.T. (1979) The origin of KREEP. Reviews of Geophysics 17, 73.

; Snyder et al., 1992

Snyder, G.A., Taylor, L.A., Neal, C.R. (1992) A chemical model for generating the sources of mare basalts: Combined equilibrium and fractional crystallization of the lunar magmasphere. Geochimica et Cosmochimica Acta 56, 3809–3823.

). Subsequent magmatic processes concluded with the eruption of lunar mare basalts (e.g., Gross and Joy, 2016

Gross, J., Joy, K.H. (2016) Evolution, Lunar: From Magma Ocean to Crust Formation. In: Cudnik, B. (ed.) Encyclopedia of Lunar Science. Springer International Publishing, Cham, 1–20.

). Experimental studies and the Hf and Nd isotope composition of mare basalts suggest that low-Ti mare basalts likely result from partial melting of lunar mafic cumulates, whereas high-Ti mare basalts are thought to reflect IBC involvement (e.g., Longhi, 1992

Longhi, J. (1992) Experimental petrology and petrogenesis of mare volcanics. Geochimica et Cosmochimica Acta 56, 2235–2251.

; Sprung et al., 2013

Sprung, P., Kleine, T., Scherer, E.E. (2013) Isotopic evidence for chondritic Lu/Hf and Sm/Nd of the Moon. Earth and Planetary Science Letters 380, 77–87.

). However, whether high-Ti basalts result from IBC assimilation by mafic low-Ti magmas (e.g., Münker, 2010

Münker, C. (2010) A high field strength element perspective on early lunar differentiation. Geochimica et Cosmochimica Acta 74, 7340–7361.

), or from the partial melting of a hybridised lunar mantle source (Snyder et al., 1992

), remains ambiguous. Titanium isotope variations in mare basalts may be used to discriminate between the two scenarios: refractory, lithophile, and fluid-immobile Ti is predominantly tetravalent albeit lunar samples may contain significant amounts of Ti³⁺ (Simon and Sutton, 2017

Simon, S.B., Sutton, S.R. (2017) Valence of Ti, V, and Cr in Apollo 14 aluminous basalts 14053 and 14072. Meteoritics & Planetary Science 52, 2051–2066.

; Leitzke et al., 2018

Leitzke, F.P., Fonseca, R.O.C., Göttlicher, J., Steininger, R., Jahn, S., Prescher, C., Lagos, M. (2018) Ti K-edge XANES study on the coordination number and oxidation state of Titanium in pyroxene, olivine, armalcolite, ilmenite, and silicate glass during mare basalt petrogenesis. Contributions to Mineralogy and Petrology 173, 103.

). The principal Ti-bearing phase in the lunar mantle is ilmenite whose VI fold coordinated crystal site preferentially incorporates lighter over heavier Ti isotopes (Schauble, 2004

Schauble, E.A. (2004) Applying Stable Isotope Fractionation Theory to New Systems. Reviews in Mineralogy and Geochemistry 55, 65–111.

). The Ti isotope composition of terrestrial samples (given as δ(⁴⁹Ti/⁴⁷Ti)_OL-Ti, relative to the Origins Lab reference material, henceforth δ⁴⁹Ti; Millet and Dauphas, 2014

Millet, M.-A., Dauphas, N. (2014) Ultra-precise titanium stable isotope measurements by double-spike high resolution MC-ICP-MS. Journal of Analytical Atomic Spectrometry 29, 1444.

) ranges between -0.046 and +1.8 ‰. Observed covariations between δ⁴⁹Ti and SiO₂, TiO_2, and FeO contents of terrestrial volcanic rocks suggest that stable Ti isotope variation is mainly driven by the onset of fractional crystallisation of Fe-Ti oxides during magmatic differentiation (Millet et al., 2016

Millet, M.-A., Dauphas, N., Greber, N.D., Burton, K.W., Dale, C.W., Debret, B., Macpherson, C.G., Nowell, G.M., Williams, H.M. (2016) Titanium stable isotope investigation of magmatic processes on the Earth and Moon. Earth and Planetary Science Letters 449, 197–205.

; Greber et al., 2017a

Greber, N.D., Dauphas, N., Bekker, A., Ptáček, M.P., Bindeman, I.N., Hofmann, A. (2017a) Titanium isotopic evidence for felsic crust and plate tectonics 3.5 billion years ago. Science 357, 1271–1274.

Greber, N.D., Dauphas, N., Puchtel, I.S., Hofmann, B.A., Arndt, N.T. (2017b) Titanium stable isotopic variations in chondrites, achondrites and lunar rocks. Geochimica et Cosmochimica Acta 213, 534–552.

; Deng et al., 2018a

Deng, Z., Moynier, F., Sossi, P.A., Chaussidon, M. (2018a) Bridging the depleted MORB mantle and the continental crust using titanium isotopes. Geochemical Perspectives Letters 9, 11–15.

, 2019

Deng, Z., Chaussidon, M., Savage, P., Robert, F., Pik, R., Moynier, F. (2019) Titanium isotopes as a tracer for the plume or island arc affinity of felsic rocks. Proceedings of the National Academy of Sciences 201809164.

; Mandl et al., 2018

Mandl, M.B., Fehr, M.A., Schönbächler, M. (2018) Titanium stable isotope fractionation on the Moon: Evidence for inter- mineral isotopic fractionation. Goldschmidt Abstracts 2018 1666.

). Consequently, the Ti isotope composition of lunar magmas might be a sensitive indicator for the crystallisation of the IBC, and its assimilation or partial melting: Millet et al. (2016)

reported δ⁴⁹Ti variations in three low-Ti mare basalts with a pooled δ⁴⁹Ti of -0.008 ± 0.019 ‰ and five high-Ti mare basalts with δ⁴⁹Ti between +0.011 and +0.033 ‰. The presence of more fractionated δ⁴⁹Ti in mare basalts, although suggested, has not yet been reported (Millet et al., 2016

). Indeed, for the urKREEP end member, as represented by the lunar meteorite Sayh al Uhaymir (SaU) 169, a tentative δ⁴⁹Ti of +0.330 ± 0.034 ‰ was obtained (Greber et al., 2017b

).

Here we report the δ⁴⁹Ti of 24 representative lunar samples in order to investigate their mantle sources in the context of three major end members: the ambient lunar mantle (low-Ti), the late stage cumulates (IBC, high-Ti), and the residual KREEP-rich component. Notably, the processes that affect δ⁴⁹Ti in lunar mantle cumulates and corresponding melts also fractionate high field strength element ratios (HFSE; Münker, 2010

Münker, C. (2010) A high field strength element perspective on early lunar differentiation. Geochimica et Cosmochimica Acta 74, 7340–7361.

). High precision HFSE, W, U, and Th data, obtained for the same samples (Thiemens et al., 2019

Thiemens, M.M., Sprung, P., Fonseca, R.O.C., Leitzke, F.P., Münker, C. (2019) Early Moon formation inferred from hafnium–tungsten systematics. Nature Geoscience 12, 696–700.

), can help to constrain δ⁴⁹Ti_urKREEP, δ⁴⁹Ti_IBC and to identify the processes leading to δ⁴⁹Ti variations in lunar samples.

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Results

Titanium isotope measurements were performed using the Thermo Neptune Plus MC-ICPMS at the University of Cologne with an intermediate precision better than ±0.023 ‰ (2 x standard deviation, henceforth s.d.) for spiked reference materials BCR-2, JB-2, OL-Ti, and Col-Ti. Total blank contribution was always less than 10 ng total Ti and is negligible compared to at least 30 µg of processed sample Ti (20 µg for 68115). More detailed information on the analytical protocol are given in the Supplementary Information. Low-Ti mare basalts show small, resolvable variations in δ⁴⁹Ti between -0.030 and +0.055 ‰ with an average of +0.010 ± 0.015 ‰ (2 s.d.; n = 12, Fig. 1, Table 1). Most high-Ti samples range from +0.009 to +0.047 in δ⁴⁹Ti (average of +0.026 ± 0.036 ‰, 2 s.d.; n = 7), sample 75035 has a comparatively high δ⁴⁹Ti value of +0.115 ‰. The high-Ti average (including 75035) yields a δ⁴⁹Ti of +0.037 ± 0.071 ‰. KREEP-rich lithologies have δ⁴⁹Ti values between +0.117 and +0.296 ‰.

**Figure 1** Measured Ti isotope compositions of lunar samples. All uncertainties unless stated otherwise are 95 % confidence interval (c.i.) of at least 6 measurements of the same aliquot. See main text and Supplementary Information for details. bce = breccia, ilm = ilmenite; QNB = quartz-normative basalt, olv = olivine, pgt = pigeonite.

Table 1 Summary of reference materials and measured samples. For reference materials, n gives the number of sequences in which the material has been measured at least 6 times. Abbreviations are the same as in Figure 1. Two aliquots of OL-Ti were run through the chemical separation process and are given as OL-Ti (chemistry).

			δ⁴⁹Ti	2 s.d.	n	95 % c.i.
	JB-2		-0.044	0.023	7	0.011
	BCR-2		-0.025	0.012	4	0.010
	OL-Ti mean		0.000	0.001	8	0.000
	OL-Ti (chemistry)		-0.001	0.030	2	0.137
	Col-Ti mean		0.206	0.021	8	0.009

	Low-Ti rocks
12022	Apollo 12	Low-Ti ilm basalt	0.029	0.022	6	0.011
12051	"	Low-Ti ilm basalt	0.030	0.022	8	0.009
12063	"	Low-Ti ilm basalt	0.055	0.022	6	0.012
12054	"	Low-Ti ilm basalt	0.028	0.026	6	0.014
12004	"	Low-Ti olv basalt	0.006	0.010	6	0.005
12053	"	Low-Ti pgt basalt	-0.013	0.026	6	0.014
15495	Apollo 15	Low-Ti ONB	0.011	0.017	6	0.009
15555	"	Low-Ti ONB	-0.008	0.026	6	0.014
15556	"	Low-Ti ONB	0.007	0.030	6	0.016
15065	"	Low-Ti QNB	-0.030	0.014	6	0.007
15058	"	Low-Ti QNB	-0.010	0.034	6	0.018
15545	"	Low-Ti QNB	0.011	0.032	6	0.017
Low-Ti mean ± 2 s.d.			0.010	0.047	12

	High-Ti rocks
10017	Apollo 11	High-Ti ilm basalt	0.009	0.024	6	0.012
10020	"	High-Ti ilm basalt	0.011	0.022	6	0.011
10057	"	High-Ti ilm basalt	0.009	0.024	6	0.012
74255	Apollo 17	High-Ti ilm basalt	0.043	0.010	6	0.005
74275	"	High-Ti ilm basalt	0.045	0.010	6	0.005
75035	"	High-Ti ilm basalt	0.115	0.025	6	0.013
79135	"	High-Ti bce	0.019	0.017	6	0.009
79035	"	High-Ti bce	0.047	0.018	6	0.010
High-Ti mean 1 ± 2 s.d.			0.026	0.036	7
High-Ti mean 2 ± 2 s.d.			0.037	0.071	8

	KREEP-rich rocks
14305	Apollo 14	KREEP-rich bce	0.296	0.030	6	0.016
14310	"	KREEP basalt	0.263	0.035	6	0.018
72275	Apollo 17	KREEP-rich bce	0.185	0.026	6	0.014
68115	Apollo 16	KREEP-rich bce	0.117	0.027	6	0.014

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Discussion

Estimating the δ⁴⁹Ti of urKREEP and the IBC. The co-genetic relationship between urKREEP and IBC permits studying the coupled δ⁴⁹Ti evolution of both reservoirs. Complementarily to the low δ⁴⁹Ti_IBC, the residual LMO is expected to have positive δ⁴⁹Ti (Millet et al., 2016

; Greber et al., 2017b

). Furthermore, U became enriched in urKREEP, whereas Ti, Hf and Zr are more compatible in ilmenite and are extracted from the LMO during IBC formation. The observed positive co-variation of δ⁴⁹Ti and U concentration in KREEP-rich samples may therefore indicate variable portions of the urKREEP-component (Fig. 2b). Our KREEP-rich sample with highest δ⁴⁹Ti and highest U concentration is identical within uncertainty to the previous estimate for δ⁴⁹Ti_urKREEP (Greber et al., 2017b

). Two KREEP-rich samples along with SaU169 have U/Hf, U/Zr and U/Ti in the range of the urKREEP estimate (calculated using data by Warren and Taylor, 2014

Warren, P.H., Taylor, G.J. (2014) The Moon. Treatise on Geochemistry (Second Edition) 2, 213–250.

), which results in a conservative estimate of δ⁴⁹Ti_urKREEP of +0.296 ± 0.067 ‰ (see Supplementary Information). To model δ⁴⁹Ti_urKREEP in a different approach, we constrained the evolution of Ti, Hf and Ta concentrations in the remaining liquid during fractional crystallisation for various LMO solidification models (Snyder et al., 1992

; Lin et al., 2017

Lin, Y., Tronche, E.J., Steenstra, E.S., van Westrenen, W. (2017) Experimental constraints on the solidification of a nominally dry lunar magma ocean. Earth and Planetary Science Letters 471, 104–116.

; Charlier et al., 2018

Charlier, B., Grove, T.L., Namur, O., Holtz, F. (2018) Crystallization of the lunar magma ocean and the primordial mantle-crust differentiation of the Moon. Geochimica et Cosmochimica Acta 234, 50–69.

; Rapp and Draper, 2018

Rapp, J.F., Draper, D.S. (2018) Fractional crystallization of the lunar magma ocean: Updating the dominant paradigm. Meteoritics & Planetary Science 53, 1432–1455.

) starting with LMO element abundances by Münker (2010)

Münker, C. (2010) A high field strength element perspective on early lunar differentiation. Geochimica et Cosmochimica Acta 74, 7340–7361.

and calculated δ⁴⁹Ti_melt using a Rayleigh distillation model (see Supplementary Information). The intersect of the respective Ti, Hf and Ta concentrations with urKREEP concentration estimates by Warren and Taylor (2014)

Warren, P.H., Taylor, G.J. (2014) The Moon. Treatise on Geochemistry (Second Edition) 2, 213–250.

together with the modelled δ⁴⁹Ti_melt-evolution line yield a range for δ⁴⁹Ti_urKREEP: all estimates using the above mentioned models and LMO concentrations of Ta (δ⁴⁹Ti_urKREEP = +0.308 ± 0.064 ‰), Hf (δ⁴⁹Ti_urKREEP = +0.290 ± 0.040 ‰) and Ti (δ⁴⁹Ti_urKREEP = +0.238 ± 0.085 ‰) are identical to our KREEP-rich sample with highest δ⁴⁹Ti (+0.296 ± 0.016 ‰), and previous estimates for δ⁴⁹Ti_urKREEP (Greber et al., 2017b

). Our models predict a final δ⁴⁹Ti_IBC between -0.006 and -0.012 ‰, consistent with estimates by Millet et al. (2016)

.

Identifying magmatic processes in lunar basalt sources. The average δ⁴⁹Ti values obtained for low- and high-Ti mare basalts (+0.010 ± 0.047 ‰ and +0.037 ± 0.071 ‰) are consistent with findings by Millet et al. (2016)

and are indistinguishable from their Bulk Silicate Earth estimate (BSE: +0.005 ± 0.005 ‰, 95 % c.i.; see Fig. 1). The δ⁴⁹Ti value of our most primitive sample, the Apollo 12 olivine basalt 12004 (possibly tapping bulk lunar mantle) is identical with the δ⁴⁹Ti_BSE estimate by Millet et al. (2016)

and the chondritic δ⁴⁹Ti value proposed by Greber et al. (2017b)

but lower than the chondritic δ⁴⁹Ti value suggested by Deng et al. (2018b)

Deng, Z., Moynier, F., van Zuilen, K., Sossi, P.A., Pringle, E.A., Chaussidon, M. (2018b) Lack of resolvable titanium stable isotopic variations in bulk chondrites. Geochimica et Cosmochimica Acta 239, 409–419.

. Possible explanations for the observed intra-group δ⁴⁹Ti variations in mare basalts include fractional crystallisation of ilmenite during petrogenesis, assimilation of an IBC- or KREEP-component during fractional crystallisation, partial melting an IBC or mantle source heterogeneity. To distinguish between these processes we first consider the results of experimental studies that simulated the petrogenesis of lunar basalts (see Supplementary Information; Longhi, 1992

Longhi, J. (1992) Experimental petrology and petrogenesis of mare volcanics. Geochimica et Cosmochimica Acta 56, 2235–2251.

and references therein): For instance, experimentally synthesised low-Ti-like samples showed that ilmenite has been one of the first solidus phases (Longhi, 1992

Longhi, J. (1992) Experimental petrology and petrogenesis of mare volcanics. Geochimica et Cosmochimica Acta 56, 2235–2251.

and references therein), which would preferentially incorporate light Ti isotopes, increasing the δ⁴⁹Ti_melt during fractional crystallisation of ilmenite (Millet et al., 2016

). High-Ti basalts from Apollo 17 were shown to originate from greater depths than Apollo 12 and 15 low-Ti mare basalts were successfully modelled by partial melting of an ilmenite-rich source (Longhi, 1992

Longhi, J. (1992) Experimental petrology and petrogenesis of mare volcanics. Geochimica et Cosmochimica Acta 56, 2235–2251.

and references therein). This can explain the observed elevated δ⁴⁹Ti_high-Ti values (See Fig. 2a; Millet et al., 2016

. In contrast, the full assimilation of an IBC-component during fractional crystallisation of a low-Ti magma would decrease the δ⁴⁹Ti value of the basaltic melt (Fig. 2a). Thus, the small intra-group variations in δ⁴⁹Ti values of low- and high-Ti basalts can best be explained by fractional crystallisation of ilmenite and melting of ilmenite-bearing sources, respectively.

In addition to experimental petrological studies, geochemical tools can help distinguish between the discussed processes. For example, the compatibility of HFSEs in ilmenite is variable (Münker, 2010

Münker, C. (2010) A high field strength element perspective on early lunar differentiation. Geochimica et Cosmochimica Acta 74, 7340–7361.

): tantalum is the most compatible HFSE in ilmenite, whereas Hf is the most incompatible (e.g., D_Ta > 1 > D_Hf; Leitzke et al., 2016

Leitzke, F.P., Fonseca, R.O.C., Michely, L.T., Sprung, P., Münker, C., Heuser, A., Blanchard, H. (2016) The effect of titanium on the partitioning behavior of high-field strength elements between silicates, oxides and lunar basaltic melts with applications to the origin of mare basalts. Chemical Geology 440, 219–238.

; or D_Ta > D_Hf, van Kan Parker et al., 2011

van Kan Parker, M., Mason, P.R.D., van Westrenen, W. (2011) Trace element partitioning between ilmenite, armalcolite and anhydrous silicate melt: Implications for the formation of lunar high-Ti mare basalts. Geochimica et Cosmochimica Acta 75, 4179–4193.

). Thus, fractional crystallisation of ilmenite would increase the δ⁴⁹Ti_melt (Millet et al., 2016

) but decrease the Ta/Hf_melt (Münker, 2010

Münker, C. (2010) A high field strength element perspective on early lunar differentiation. Geochimica et Cosmochimica Acta 74, 7340–7361.

). In contrast, partial melting of an IBC component would increase the Ta/Hf_melt and the δ⁴⁹Ti_melt value (D_Ta ~ 2 x D_Hf for ilmenite, e.g., Leitzke et al., 2016

). Apollo 12 low-Ti ilmenite basalts show lower Ta/Hf and positive δ⁴⁹Ti relative to the most primitive lunar basalt analysed in this study, (12004, see Figs. 1, 2b), indicating the early fractional crystallisation of ilmenite, which is consistent with experimental results (Longhi, 1992

Longhi, J. (1992) Experimental petrology and petrogenesis of mare volcanics. Geochimica et Cosmochimica Acta 56, 2235–2251.

and references therein). Relatively low δ⁴⁹Ti values in Apollo 15 low-Ti basalts may indicate the assimilation of an IBC material (Longhi, 1992

Longhi, J. (1992) Experimental petrology and petrogenesis of mare volcanics. Geochimica et Cosmochimica Acta 56, 2235–2251.

and references therein). However, assimilation of an IBC component seems inconsistent with relatively low Ta/Hf and comparatively low TiO₂ contents of ~1.3 %. The assimilation of a KREEP-component would cause a substantial increase in the δ⁴⁹Ti and U concentration of the melt while barely fractionating Ta/Hf. Such trends are not observed indicating that KREEP components played an insignificant role during the petrogenesis of low- and high-Ti basalts (Fig. 2c). Apollo 17 high-Ti samples are rich in TiO₂, exhibit relatively low MgO/TiO₂but high δ⁴⁹Ti and higher Ta/Hf relative to our most primitive sample. In agreement with the experimental evidence, this geochemical pattern strongly indicates partial melting of an IBC component during the petrogenesis of Apollo 17 high-Ti basalts (Longhi, 1992

Longhi, J. (1992) Experimental petrology and petrogenesis of mare volcanics. Geochimica et Cosmochimica Acta 56, 2235–2251.

and references therein). These processes are further modelled and discussed in the Supplementary Information.

**Figure 2** Plots of **(a)** δ⁴⁹Ti vs. MgO/TiO₂, **(b)** δ⁴⁹Ti vs. Ta/Hf and **(c)** δ⁴⁹Ti vs. U that can be used to discriminate between processes leading to variations in δ⁴⁹Ti. Symbols are the same as in Figure 1, black arrows indicate the direction in which a process would influence the values along y- and x-axes. Partial melting assumes the presence of ilmenite in the source, fractional crystallisation always implies fractional crystallisation of ilmenite. AFC implies the assimilation of an IBC component during ilmenite-free fractional crystallisation of a low-Ti magma. **(b)** The estimated Ta/Hf value of urKREEP is ~0.11 (Warren and Taylor, 2014
Warren, P.H., Taylor, G.J. (2014) The Moon. *Treatise on Geochemistry (Second Edition)* 2, 213–250.
). **(c)** Contamination by urKREEP (coloured arrow), would imply higher U contents (not observed). urKREEP is based on our first model (see Supplementary Information).

Comparison with Fe isotope systematics. Previous studies observed a bimodal distribution of δ⁵⁷Fe values for lunar low-Ti and high-Ti basalts: higher δ⁵⁷Fe values in high-Ti basalts were attributed to the presence of ilmenite during partial melting (Sossi and Moynier, 2017

Sossi, P.A., Moynier, F. (2017) Chemical and isotopic kinship of iron in the Earth and Moon deduced from the lunar Mg-Suite. Earth and Planetary Science Letters 471, 125–135.

; Sossi and O’Neill, 2017

Sossi, P.A., O’Neill, H.St.C. (2017) The effect of bonding environment on iron isotope fractionation between minerals at high temperature. Geochimica et Cosmochimica Acta 196, 121–143.

), which is consistent with experimental studies (Longhi, 1992

Longhi, J. (1992) Experimental petrology and petrogenesis of mare volcanics. Geochimica et Cosmochimica Acta 56, 2235–2251.

and references therein) as well as our Ta/Hf and δ⁴⁹Ti data. However, intra-group variation in δ⁵⁷Fe of low-Ti basalts was not observed (Weyer et al., 2005

Weyer, S., Anbar, A., Brey, G., Munker, C., Mezger, K., Woodland, A. (2005) Iron isotope fractionation during planetary differentiation. Earth and Planetary Science Letters 240, 251–264.

; Sossi and Moynier, 2017

Sossi, P.A., Moynier, F. (2017) Chemical and isotopic kinship of iron in the Earth and Moon deduced from the lunar Mg-Suite. Earth and Planetary Science Letters 471, 125–135.

; Poitrasson et al., 2019

Poitrasson, F., Zambardi, T., Magna, T., Neal, C.R. (2019) A reassessment of the iron isotope composition of the Moon and its implications for the accretion and differentiation of terrestrial planets. Geochimica et Cosmochimica Acta 267, 257–274.

) as the δ⁵⁷Fe of low-Ti basalts is mainly controlled by fractional crystallisation of olivine and pyroxene, which would preferentially incorporate light Fe isotopes, similar to ilmenite (Δ⁵⁷Fe_Ilm-Ol = +0.01 ‰; Sossi and O’Neill, 2017

Sossi, P.A., O’Neill, H.St.C. (2017) The effect of bonding environment on iron isotope fractionation between minerals at high temperature. Geochimica et Cosmochimica Acta 196, 121–143.

). Thus, δ⁴⁹Ti appear more appropriate to discriminate better between the petrogenetic processes culminating in lunar basalts. Additional Cr, V and Hf isotope systematics are discussed in the Supplementary Information.

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Conclusion

New Ti isotope data for a representative set of lunar samples show that there is a clear offset between KREEP-rich samples and mare basalts, in agreement with previous work (Millet et al., 2016

; Greber et al., 2017b

). Our data reveal intra-group variation amongst olivine- and quartz-normative and (low-Ti) ilmenite mare basalts with the latter recording higher δ⁴⁹Ti than the former. High-Ti mare basalts have overall higher δ⁴⁹Ti. The δ⁴⁹Ti of our lunar sample suite, coupled with HFSE data, suggests that the fractional crystallisation of ilmenite and partial melting of an IBC-component are the principal processes affecting the δ⁴⁹Ti of Apollo 12 low-Ti mare basalts, and of Apollo 17 high-Ti mare basalts, respectively. This conclusion is consistent with results of previously published experimental studies (Longhi, 1992

Longhi, J. (1992) Experimental petrology and petrogenesis of mare volcanics. Geochimica et Cosmochimica Acta 56, 2235–2251.

and references therein). This is in excellent agreement with previous experimental data and the heavy δ⁵⁷Fe of high-Ti mare basalts (Longhi, 1992

Longhi, J. (1992) Experimental petrology and petrogenesis of mare volcanics. Geochimica et Cosmochimica Acta 56, 2235–2251.

; Weyer et al., 2005

Weyer, S., Anbar, A., Brey, G., Munker, C., Mezger, K., Woodland, A. (2005) Iron isotope fractionation during planetary differentiation. Earth and Planetary Science Letters 240, 251–264.

; Sossi and Moynier, 2017

Sossi, P.A., Moynier, F. (2017) Chemical and isotopic kinship of iron in the Earth and Moon deduced from the lunar Mg-Suite. Earth and Planetary Science Letters 471, 125–135.

; Charlier et al., 2018

). Based on coupled HFSE and δ⁴⁹Ti data, the petrogenesis of high-Ti mare basalts by assimilation of IBC-component by low-Ti magma is unlikely.

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Acknowledgements

We thank CAPTEM for providing lunar samples and Horst Marschall for handling the manuscript. The authors would like to thank Marc-Alban Millet and Nicolas Greber for sharing the OL-Ti reference material, Wim van Westrenen and one anonymous reviewer for constructive comments that greatly improved the manuscript. ROCF is grateful for funding of a Heisenberg Professorship by the Deutsche Forschungsgemeinschaft (DFG grants FO 698/6-1 and FO 698/11-1). CM acknowledges funding by the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (grant agreement No. 669666). SK was partially funded through a UoC Advanced Post Doc grant within the Excellence Initiative to PS and acknowledges the UoC Graduate School of Geosciences for providing a fellowship (GSGS-2019X-07).

Editor: Horst R. Marschall

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References

Asphaug, E. (2014) Impact Origin of the Moon? Annual Review of Earth and Planetary Sciences 42, 551–578.

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It is widely accepted that the Moon formed as the result of an impact between one or more planetesimals and the proto-Earth (e.g., Asphaug, 2014).
View in article

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To model δ⁴⁹Ti_urKREEP in a different approach, we constrained the evolution of Ti, Hf and Ta concentrations in the remaining liquid during fractional crystallisation for various LMO solidification models (Snyder et al., 1992; Lin et al., 2017; Charlier et al., 2018; Rapp and Draper, 2018) starting with LMO element abundances by Münker (2010) and calculated δ⁴⁹Ti_melt using a Rayleigh distillation model (see Supplementary Information).
View in article
This is in excellent agreement with previous experimental data and the heavy δ⁵⁷Fe of high-Ti mare basalts (Longhi, 1992; Weyer et al., 2005; Sossi and Moynier, 2017; Charlier et al., 2018).
View in article

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Deng, Z., Moynier, F., Sossi, P.A., Chaussidon, M. (2018a) Bridging the depleted MORB mantle and the continental crust using titanium isotopes. Geochemical Perspectives Letters 9, 11–15.

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The δ⁴⁹Ti value of our most primitive sample, the Apollo 12 olivine basalt 12004 (possibly tapping bulk lunar mantle) is identical with the δ⁴⁹Ti_BSE estimate by Millet et al. (2016) and the chondritic δ⁴⁹Ti value proposed by Greber et al. (2017b) but lower than the chondritic δ⁴⁹Ti value suggested by Deng et al. (2018b).
View in article

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Observed covariations between δ⁴⁹Ti and SiO₂, TiO₂, and FeO contents of terrestrial volcanic rocks suggest that stable Ti isotope variation is mainly driven by the onset of fractional crystallisation of Fe-Ti oxides during magmatic differentiation (Millet et al., 2016; Greber et al., 2017a,b; Deng et al., 2018a, 2019; Mandl et al., 2018).
View in article
Indeed, for the urKREEP end member, as represented by the lunar meteorite Sayh al Uhaymir (SaU) 169, a tentative δ⁴⁹Ti of +0.330 ± 0.034 ‰ was obtained (Greber et al., 2017b).
View in article
Complementarily to the low δ⁴⁹Ti_IBC, the residual LMO is expected to have positive δ⁴⁹Ti (Millet et al., 2016; Greber et al., 2017b).
View in article
Our KREEP-rich sample with highest δ⁴⁹Ti and highest U concentration is identical within uncertainty to the previous estimate for δ⁴⁹Ti_urKREEP (Greber et al., 2017b).
View in article
The intersect of the respective Ti, Hf and Ta concentrations with urKREEP concentration estimates by Warren and Taylor (2014) together with the modelled δ⁴⁹Ti_melt-evolution line yield a range for δ⁴⁹Ti_urKREEP: all estimates using the above mentioned models and LMO concentrations of Ta (δ⁴⁹Ti_urKREEP = +0.308 ± 0.064 ‰), Hf (δ⁴⁹Ti_urKREEP = +0.290 ± 0.040 ‰) and Ti (δ⁴⁹Ti_urKREEP = +0.238 ± 0.085 ‰) are identical to our KREEP-rich sample with highest δ⁴⁹Ti (+0.296 ± 0.016 ‰), and previous estimates for δ⁴⁹Ti_urKREEP (Greber et al., 2017b).
View in article
The δ⁴⁹Ti value of our most primitive sample, the Apollo 12 olivine basalt 12004 (possibly tapping bulk lunar mantle) is identical with the δ⁴⁹Ti_BSE estimate by Millet et al. (2016) and the chondritic δ⁴⁹Ti value proposed by Greber et al. (2017b) but lower than the chondritic δ⁴⁹Ti value suggested by Deng et al. (2018b).
View in article
New Ti isotope data for a representative set of lunar samples show that there is a clear offset between KREEP-rich samples and mare basalts, in agreement with previous work (Millet et al., 2016; Greber et al., 2017b).
View in article

Gross, J., Joy, K.H. (2016) Evolution, Lunar: From Magma Ocean to Crust Formation. In: Cudnik, B. (ed.) Encyclopedia of Lunar Science. Springer International Publishing, Cham, 1–20.

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Subsequent magmatic processes concluded with the eruption of lunar mare basalts (e.g., Gross and Joy, 2016).
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For example, the compatibility of HFSEs in ilmenite is variable (Münker, 2010): tantalum is the most compatible HFSE in ilmenite, whereas Hf is the most incompatible (e.g., D_Ta > 1 > D_Hf; Leitzke et al., 2016; or D_Ta > D_Hf, van Kan Parker et al., 2011).
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In contrast, partial melting of an IBC component would increase the Ta/Hf_melt and the δ⁴⁹Timelt value (D_Ta ~ 2 x D_Hf for ilmenite, e.g., Leitzke et al., 2016).
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Titanium isotope variations in mare basalts may be used to discriminate between the two scenarios: refractory, lithophile, and fluid-immobile Ti is predominantly tetravalent albeit lunar samples may contain significant amounts of Ti³⁺ (Simon and Sutton, 2017; Leitzke et al., 2018).
View in article

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Longhi, J. (1992) Experimental petrology and petrogenesis of mare volcanics. Geochimica et Cosmochimica Acta 56, 2235–2251.

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Experimental studies and the Hf and Nd isotope composition of mare basalts suggest that low-Ti mare basalts likely result from partial melting of lunar mafic cumulates, whereas high-Ti mare basalts are thought to reflect IBC involvement (e.g., Longhi, 1992; Sprung et al., 2013).
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To distinguish between these processes we first consider the results of experimental studies that simulated the petrogenesis of lunar basalts (see Supplementary Information; Longhi, 1992 and references therein):
View in article
For instance, experimentally synthesised low-Ti-like samples showed that ilmenite has been one of the first solidus phases (Longhi, 1992 and references therein), which would preferentially incorporate light Ti isotopes, increasing the δ⁴⁹Ti_melt during fractional crystallisation of ilmenite (Millet et al., 2016).
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High-Ti basalts from Apollo 17 were shown to originate from greater depths than Apollo 12 and 15 low-Ti mare basalts were successfully modelled by partial melting of an ilmenite-rich source (Longhi, 1992 and references therein).
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Apollo 12 low-Ti ilmenite basalts show lower Ta/Hf and positive δ⁴⁹Ti relative to the most primitive lunar basalt analysed in this study, (12004, see Figs. 1, 2b), indicating the early fractional crystallisation of ilmenite, which is consistent with experimental results (Longhi, 1992 and references therein).
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Relatively low δ⁴⁹Ti values in Apollo 15 low-Ti basalts may indicate the assimilation of an IBC material (Longhi, 1992 and references therein).
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In agreement with the experimental evidence, this geochemical pattern strongly indicates partial melting of an IBC component during the petrogenesis of Apollo 17 high-Ti basalts (Longhi, 1992 and references therein).
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Previous studies observed a bimodal distribution of δ⁵⁷Fe values for lunar low-Ti and high-Ti basalts: higher δ⁵⁷Fe values in high-Ti basalts were attributed to the presence of ilmenite during partial melting (Sossi and Moynier, 2017; Sossi and O’Neill, 2017), which is consistent with experimental studies (Longhi, 1992 and references therein) as well as our Ta/Hf and δ⁴⁹Ti data.
View in article
This conclusion is consistent with results of previously published experimental studies (Longhi, 1992 and references therein).
View in article
This is in excellent agreement with previous experimental data and the heavy δ⁵⁷Fe of high-Ti mare basalts (Longhi, 1992; Weyer et al., 2005; Sossi and Moynier, 2017; Charlier et al., 2018).
View in article

Mandl, M.B., Fehr, M.A., Schönbächler, M. (2018) Titanium stable isotope fractionation on the Moon: Evidence for inter- mineral isotopic fractionation. Goldschmidt Abstracts 2018 1666.

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Millet, M.-A., Dauphas, N. (2014) Ultra-precise titanium stable isotope measurements by double-spike high resolution MC-ICP-MS. Journal of Analytical Atomic Spectrometry 29, 1444.

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The Ti isotope composition of terrestrial samples (given as δ(⁴⁹Ti/⁴⁷Ti)OL-Ti, relative to the Origins Lab reference material, henceforth δ⁴⁹Ti; Millet and Dauphas, 2014) ranges between -0.046 and +1.8 ‰.
View in article

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Observed covariations between δ⁴⁹Ti and SiO₂, TiO₂, and FeO contents of terrestrial volcanic rocks suggest that stable Ti isotope variation is mainly driven by the onset of fractional crystallisation of Fe-Ti oxides during magmatic differentiation (Millet et al., 2016; Greber et al., 2017a,b; Deng et al., 2018a, 2019; Mandl et al., 2018).
View in article
Consequently, the Ti isotope composition of lunar magmas might be a sensitive indicator for the crystallisation of the IBC, and its assimilation or partial melting: Millet et al. (2016) reported δ⁴⁹Ti variations in three low-Ti mare basalts with a pooled δ⁴⁹Ti of -0.008 ± 0.019 ‰ and five high-Ti mare basalts with δ⁴⁹Ti between +0.011 and +0.033 ‰.
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The presence of more fractionated δ⁴⁹Ti in mare basalts, although suggested, has not yet been reported (Millet et al., 2016).
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Complementarily to the low δ⁴⁹Ti_IBC, the residual LMO is expected to have positive δ⁴⁹Ti (Millet et al., 2016; Greber et al., 2017b).
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Our models predict a final δ⁴⁹Ti_IBC between -0.006 and -0.012 ‰, consistent with estimates by Millet et al. (2016).
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The average δ⁴⁹Ti values obtained for low- and high-Ti mare basalts (+0.010 ± 0.047 ‰ and +0.037 ± 0.071 ‰) are consistent with findings by Millet et al. (2016) and are indistinguishable from their Bulk Silicate Earth estimate (BSE: +0.005 ± 0.005 ‰, 95 % c.i.; see Fig. 1).
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The δ⁴⁹Ti value of our most primitive sample, the Apollo 12 olivine basalt 12004 (possibly tapping bulk lunar mantle) is identical with the δ⁴⁹Ti_BSE estimate by Millet et al. (2016) and the chondritic δ⁴⁹Ti value proposed by Greber et al. (2017b) but lower than the chondritic δ⁴⁹Ti value suggested by Deng et al. (2018b).
View in article
For instance, experimentally synthesised low-Ti-like samples showed that ilmenite has been one of the first solidus phases (Longhi, 1992 and references therein), which would preferentially incorporate light Ti isotopes, increasing the δ⁴⁹Ti_melt during fractional crystallisation of ilmenite (Millet et al., 2016).
View in article
This can explain the observed elevated δ⁴⁹Ti_high-Ti values (See Fig. 2a; Millet et al., 2016).
View in article
Thus, fractional crystallisation of ilmenite would increase the δ⁴⁹Ti_melt (Millet et al., 2016) but decrease the Ta/Hf_melt (Münker, 2010).
View in article
New Ti isotope data for a representative set of lunar samples show that there is a clear offset between KREEP-rich samples and mare basalts, in agreement with previous work (Millet et al., 2016; Greber et al., 2017b).
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Münker, C. (2010) A high field strength element perspective on early lunar differentiation. Geochimica et Cosmochimica Acta 74, 7340–7361.

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However, whether high-Ti basalts result from IBC assimilation by mafic low-Ti magmas (e.g., Münker, 2010), or from the partial melting of a hybridised lunar mantle source (Snyder et al., 1992), remains ambiguous.
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Notably, the processes that affect δ⁴⁹Ti in lunar mantle cumulates and corresponding melts also fractionate high field strength element ratios (HFSE; Münker, 2010).
View in article
To model δ⁴⁹Ti_urKREEP in a different approach, we constrained the evolution of Ti, Hf and Ta concentrations in the remaining liquid during fractional crystallisation for various LMO solidification models (Snyder et al., 1992; Lin et al., 2017; Charlier et al., 2018; Rapp and Draper, 2018) starting with LMO element abundances by Münker (2010) and calculated δ⁴⁹Ti_melt using a Rayleigh distillation model (see Supplementary Information).
View in article
For example, the compatibility of HFSEs in ilmenite is variable (Münker, 2010): tantalum is the most compatible HFSE in ilmenite, whereas Hf is the most incompatible (e.g., D_Ta > 1 > D_Hf; Leitzke et al., 2016; or D_Ta > D_Hf, van Kan Parker et al., 2011).
View in article
Thus, fractional crystallisation of ilmenite would increase the δ⁴⁹Ti_melt (Millet et al., 2016) but decrease the Ta/Hf_melt (Münker, 2010).
View in article

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Rapp, J.F., Draper, D.S. (2018) Fractional crystallization of the lunar magma ocean: Updating the dominant paradigm. Meteoritics & Planetary Science 53, 1432–1455.

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Schauble, E.A. (2004) Applying Stable Isotope Fractionation Theory to New Systems. Reviews in Mineralogy and Geochemistry 55, 65–111.

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The principal Ti-bearing phase in the lunar mantle is ilmenite whose VI fold coordinated crystal site preferentially incorporates lighter over heavier Ti isotopes (Schauble, 2004).
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Simon, S.B., Sutton, S.R. (2017) Valence of Ti, V, and Cr in Apollo 14 aluminous basalts 14053 and 14072. Meteoritics & Planetary Science 52, 2051–2066.

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The last phases to solidify in the impact-induced Lunar Magma Ocean (LMO) were K-, REE-, and P-rich residual components (urKREEP) and complementarily an ilmenite-bearing cumulate (IBC; Warren and Wasson, 1979; Snyder et al., 1992).
View in article
However, whether high-Ti basalts result from IBC assimilation by mafic low-Ti magmas (e.g., Münker, 2010), or from the partial melting of a hybridised lunar mantle source (Snyder et al., 1992), remains ambiguous.
View in article
To model δ⁴⁹Ti_urKREEP in a different approach, we constrained the evolution of Ti, Hf and Ta concentrations in the remaining liquid during fractional crystallisation for various LMO solidification models (Snyder et al., 1992; Lin et al., 2017; Charlier et al., 2018; Rapp and Draper, 2018) starting with LMO element abundances by Münker (2010) and calculated δ⁴⁹Ti_melt using a Rayleigh distillation model (see Supplementary Information).
View in article

Sossi, P.A., Moynier, F. (2017) Chemical and isotopic kinship of iron in the Earth and Moon deduced from the lunar Mg-Suite. Earth and Planetary Science Letters 471, 125–135.

Show in context

Previous studies observed a bimodal distribution of δ⁵⁷Fe values for lunar low-Ti and high-Ti basalts: higher δ⁵⁷Fe values in high-Ti basalts were attributed to the presence of ilmenite during partial melting (Sossi and Moynier, 2017; Sossi and O’Neill, 2017), which is consistent with experimental studies (Longhi, 1992 and references therein) as well as our Ta/Hf and δ⁴⁹Ti data.
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However, intra-group variation in δ⁵⁷Fe of low-Ti basalts was not observed (Weyer et al., 2005; Sossi and Moynier, 2017; Poitrasson et al., 2019) as the δ⁵⁷Fe of low-Ti basalts is mainly controlled by fractional crystallisation of olivine and pyroxene, which would preferentially incorporate light Fe isotopes, similar to ilmenite (Δ⁵⁷Fe_Ilm-Ol = +0.01 ‰; Sossi and O’Neill, 2017).
View in article
This is in excellent agreement with previous experimental data and the heavy δ⁵⁷Fe of high-Ti mare basalts (Longhi, 1992; Weyer et al., 2005; Sossi and Moynier, 2017; Charlier et al., 2018).
View in article

Sossi, P.A., O’Neill, H.St.C. (2017) The effect of bonding environment on iron isotope fractionation between minerals at high temperature. Geochimica et Cosmochimica Acta 196, 121–143.

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Sprung, P., Kleine, T., Scherer, E.E. (2013) Isotopic evidence for chondritic Lu/Hf and Sm/Nd of the Moon. Earth and Planetary Science Letters 380, 77–87.

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Thiemens, M.M., Sprung, P., Fonseca, R.O.C., Leitzke, F.P., Münker, C. (2019) Early Moon formation inferred from hafnium–tungsten systematics. Nature Geoscience 12, 696–700.

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High precision HFSE, W, U, and Th data, obtained for the same samples (Thiemens et al., 2019), can help to constrain δ⁴⁹Ti_urKREEP, δ⁴⁹Ti_IBC and to identify the processes leading to δ⁴⁹Ti variations in lunar samples.
View in article

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Warren, P.H., Taylor, G.J. (2014) The Moon. Treatise on Geochemistry (Second Edition) 2, 213–250.

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Two KREEP-rich samples along with SaU169 have U/Hf, U/Zr and U/Ti in the range of the urKREEP estimate (calculated using data by Warren and Taylor, 2014), which results in a conservative estimate of δ⁴⁹Ti_urKREEP of +0.296 ± 0.067 ‰ (see Supplementary Information).
View in article
The intersect of the respective Ti, Hf and Ta concentrations with urKREEP concentration estimates by Warren and Taylor (2014) together with the modelled δ⁴⁹Ti_melt-evolution line yield a range for δ⁴⁹Ti_urKREEP: all estimates using the above mentioned models and LMO concentrations of Ta (δ⁴⁹Ti_urKREEP = +0.308 ± 0.064 ‰), Hf (δ⁴⁹Ti_urKREEP = +0.290 ± 0.040 ‰) and Ti (δ⁴⁹Ti_urKREEP = +0.238 ± 0.085 ‰) are identical to our KREEP-rich sample with highest δ⁴⁹Ti (+0.296 ± 0.016 ‰), and previous estimates for δ⁴⁹Ti_urKREEP (Greber et al., 2017b).
View in article

Warren, P.H., Wasson, J.T. (1979) The origin of KREEP. Reviews of Geophysics 17, 73.

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Weyer, S., Anbar, A., Brey, G., Munker, C., Mezger, K., Woodland, A. (2005) Iron isotope fractionation during planetary differentiation. Earth and Planetary Science Letters 240, 251–264.

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However, intra-group variation in δ⁵⁷Fe of low-Ti basalts was not observed (Weyer et al., 2005; Sossi and Moynier, 2017; Poitrasson et al., 2019) as the δ⁵⁷Fe of low-Ti basalts is mainly controlled by fractional crystallisation of olivine and pyroxene, which would preferentially incorporate light Fe isotopes, similar to ilmenite (Δ⁵⁷Fe_Ilm-Ol = +0.01 ‰; Sossi and O’Neill, 2017).
View in article
This is in excellent agreement with previous experimental data and the heavy δ⁵⁷Fe of high-Ti mare basalts (Longhi, 1992; Weyer et al., 2005; Sossi and Moynier, 2017; Charlier et al., 2018).
View in article

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Supplementary Information

The Supplementary Information includes:

Sample Description
Methods
Results
Discussion
Tables S-1 to S-7
Figures S-1 to S-9
Supplementary Information References

Download the Supplementary Information (PDF).

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Figures and Tables

			δ⁴⁹Ti	2 s.d.	n	95 % c.i.
	JB-2		-0.044	0.023	7	0.011
	BCR-2		-0.025	0.012	4	0.010
	OL-Ti mean		0.000	0.001	8	0.000
	OL-Ti (chemistry)		-0.001	0.030	2	0.137
	Col-Ti mean		0.206	0.021	8	0.009

	Low-Ti rocks
12022	Apollo 12	Low-Ti ilm basalt	0.029	0.022	6	0.011
12051	"	Low-Ti ilm basalt	0.030	0.022	8	0.009
12063	"	Low-Ti ilm basalt	0.055	0.022	6	0.012
12054	"	Low-Ti ilm basalt	0.028	0.026	6	0.014
12007	"	Low-Ti olv basalt	0.006	0.010	6	0.005
12053	"	Low-Ti pgt basalt	-0.013	0.026	6	0.014
15495	Apollo 15	Low-Ti ONB	0.011	0.017	6	0.009
15555	"	Low-Ti ONB	-0.008	0.026	6	0.014
15556	"	Low-Ti ONB	0.007	0.030	6	0.016
15065	"	Low-Ti QNB	-0.030	0.014	6	0.007
15058	"	Low-Ti QNB	-0.010	0.034	6	0.018
15545	"	Low-Ti QNB	0.011	0.032	6	0.017
Low-Ti mean ± 2 s.d.			0.010	0.047	12

	High-Ti rocks
10017	Apollo 11	High-Ti ilm basalt	0.009	0.024	6	0.012
10020	"	High-Ti ilm basalt	0.011	0.022	6	0.011
10057	"	High-Ti ilm basalt	0.009	0.024	6	0.012
74255	Apollo 17	High-Ti ilm basalt	0.043	0.010	6	0.005
74275	"	High-Ti ilm basalt	0.045	0.010	6	0.005
75035	"	High-Ti ilm basalt	0.115	0.025	6	0.013
79135	"	High-Ti bce	0.019	0.017	6	0.009
79035	"	High-Ti bce	0.047	0.018	6	0.010
High-Ti mean 1 ± 2 s.d.			0.026	0.036	7
High-Ti mean 2 ± 2 s.d.			0.037	0.071	8

	KREEP-rich rocks
14305	Apollo 14	KREEP-rich bce	0.296	0.030	6	0.016
14310	"	KREEP basalt	0.263	0.035	6	0.018
72275	Apollo 17	KREEP-rich bce	0.185	0.026	6	0.014
68115	Apollo 16	KREEP-rich bce	0.117	0.027	6	0.014

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