{"title":"Origin of Archean Pb isotope variability through open-system Paleoarchean crustal anatexis","authors":"M.I.H. Hartnady, C.L. Kirkand, S.P. Johnson, R.H. Smithies, L.S. Doucet, D.R. Mole","doi":"10.1130/g51507.1","DOIUrl":null,"url":null,"abstract":"Lead isotopic data imply that thorium and uranium were fractionated from one another in Earth’s early history; however, the origin of this fractionation is poorly understood. We report new in situ Pb isotope data from orthoclase in 144 granites sampled across the Archean Yilgarn craton (Western Australia) to characterize its Pb isotope variability and evolution. Granite Pb isotope compositions reveal three Pb sources, a mantle-derived Pb reservoir and two crustal Pb reservoirs, distinguished by their implied source 232Th/238U (κPb). High-κPb granites reflect sources with high 232Th/238U (~4.7) and are largely co-located with Eoarchean–Paleoarchean crust. The Pb isotope compositions of most granites, and those of volcanic-hosted massive sulfide (VHMS) and gold ores, define a mixing array between a mantle Pb source and a Th-rich Eoarchean–Paleoarchean source. Pb isotope modeling indicates that the high-κPb source rocks experienced Th/U fractionation at ca. 3.3 Ga. As Th/U fractionation in the Yilgarn craton must have occurred before Earth’s atmosphere was oxygenated, subaerial weathering cannot explain the apparent differences in their geochemical behavior. Instead, the high Th/U source reflects Eoarchean–Paleoarchean rocks that experienced prior high-temperature metamorphism, partial melting, and melt loss in the presence of a Th-sequestering mineral like monazite. Archean Pb isotope variability thus has its origins in open-system high-temperature metamorphic processes responsible for the differentiation and stabilization of Earth’s continental crust.Thorium and uranium are highly incompatible trace elements that are partitioned into Earth’s crust over geological time (Galer and O’nions, 1985; Allègre et al., 1986). Being two of the main heat-producing elements in the silicate Earth, understanding their partitioning between different geochemical reservoirs is important for tracking our planet’s thermal evolution and internal differentiation.Thorium has a single valence state (4+) whereas U exists in two valence states (4+ and 6+), with the highly water-soluble hexavalent species dominant under oxidized surface conditions (Zartman and Haines, 1988). Since the Great Oxidation Event (2.5–2.4 Ga), U has preferentially been recycled into the mantle, causing a progressive lowering of the Th/U ratio in the mantle and in rocks derived from it (McCulloch, 1993; Collerson and Kamber, 1999; Elliott et al., 1999; Zartman and Richardson, 2005). However, in the Archean, when Earth’s atmosphere was largely devoid of oxygen, neither mantle melting, fractional crystallization, nor weathering and recycling processes could have fractionated U and Th. Hence, it is thought the geochemical behavior of these elements was identical from the surface down to the upper mantle (Liu et al., 2019). Nevertheless, some lines of evidence show that Th and U were fractionated from one another early in Earth’s history. For example, variability in the 208Pb/204Pb ratios of some Archean rocks and ore minerals require an older Pb source with super-chondritic 232Th/238U (Robertson and Cumming, 1968; Perring and McNaughton, 1992). However, there has been no satisfactory explanation for how Th and U were fractionated from one another this early in Earth’s history.The Yilgarn craton in Western Australia provides an ideal laboratory for investigating the origins of Archean Pb isotope variability. Large volumes of granite were emplaced within a restricted time interval (2.7–2.6 Ga), via reworking of pre-existing crust of variable age (3.8–2.7 Ga; Mole et al., 2019). As the variability in initial Pb isotope composition of granites depends on the 238U/204Pb ratio (μ) and 232Th/238U ratio (κ) of their source rocks and the duration of radioactive decay, any variability in source 232Th/238U will manifest itself in their initial Pb isotope compositions. Analyzing the initial Pb isotope composition of these granites affords the opportunity to probe the deep crustal composition and architecture, and address the origins of Pb isotope variability in ancient crust. Although many rock-forming silicate minerals have non-zero U/Pb ratios, meaning their Pb isotope compositions change over time, one mineral that can yield initial Pb isotope ratios is orthoclase (Gancarz and Wasserburg, 1977).We report new orthoclase laser ablation–inductively coupled plasma–mass spectrometry Pb isotope data from 144 samples of granite feldspar from across the Yilgarn craton. A detailed method description and data tables are provided in the Supplemental Material1.The Yilgarn craton comprises several terranes (Fig. 1). The Narryer terrane occupies the northwest corner of the craton and contains felsic gneisses with protolith ages from 3.73 Ga to 3.37 Ga, and subordinate supracrustal belts (Kinny et al., 1988; Kemp et al., 2018). Together with the South West and Youanmi terranes, they make up the West Yilgarn, which contains evidence for shared 3.00–2.90, 2.80, and 2.73–2.72 Ga magmatism generally characterized by unradiogenic Nd and Hf isotope compositions, indicating an older Paleoarchean source for this region (Mole et al., 2019). The West Yilgarn abuts the Eastern Goldfields Superterrane (EGST) along the Ida fault (Fig. 1). The EGST is dominated by felsic igneous rocks and supracrustal sequences (greenstone belts) formed between 2.72 and 2.66 Ga, representing a period of widespread basalt-komatiite magmatism, which was followed by craton-wide emplacement of tonalite-trondjhemite-granodiorite (TTG) and subsequently K-rich granite, inferred to reflect a widespread lower-crustal melting event (Smithies et al., 2019).Figure 2 shows the Pb isotope ratios of the granite samples along with a compilation of data from volcanic-hosted massive sulfide (VHMS) and Au ores from across the craton, and the terrestrial Pb isotope evolution model of Maltese and Mezger (2020). The range of Pb isotope compositions from the granites is identical to those of the ores (Fig. 2A and 2B), which are both consistent with modeled single-stage paleogeochrons for rocks formed between 2.7 and 2.6 Ga (Figs. 2A and 2C; Table DR1 in the Supplemental Material). The least-radiogenic granites have Pb isotope compositions approaching those of the VHMS ores at Teutonic Bore, which may approximate mantle Pb isotope compositions at that time (Hannington et al., 2005). More than 50% of the samples overlap the initial Pb isotope compositions of Au deposits from the Wiluna-Leonora and Menzies-Kambalda regions, whereas the most-radiogenic samples scatter to higher 206Pb/204Pb and 207Pb/204Pb ratios, like those associated with the Stennet Rocks granite and Au ores from the Norseman area (Figs. 2A and 2C).The spatial variation of granite Pb isotope source model ages using interpolated isotopic maps shows a long-wavelength structure like that observed in zircon initial Hf and whole-rock initial Nd isotopes (Figs. 3A–3C). Specifically, the Youanmi terrane exhibits higher 206Pb/204Pb and 207Pb/204Pb ratios (older source model ages) and Hf model ages as old as 3.8–3.6 Ga (Fig. 3A), indicating granites in these regions sampled old felsic crust with sub-chondritic 176Lu/177Hf and 147Sm/144Nd ratios and μ higher than the bulk Earth model. Across the Ida fault, there is a gradient in both Hf model ages and granite 207Pb/204Pb source ages (Figs. 3A–3C). The EGST granites exhibit less-radiogenic Pb isotope compositions and younger Hf model ages (<2.9 Ga), indicating magmatism in the EGST was derived from source rocks with a greater amount of mantle-derived material. All the isotopic data sets are broadly consistent with the upper mantle velocity structure, which implies a density (and hence age) gradient in subcratonic lithospheric mantle (Fig. 3D; Kennett et al., 2013).Whereas variable 206Pb/204Pb and 207Pb/204Pb ratios reflect mixing between sources with different 238U/204Pb fractionation histories, variation in 208Pb/204Pb ratios reveals sources with different 232Th/238U fractionation histories. A plot of 208Pb/204Pb versus 206Pb/204Pb reveals the high-μ crustal source comprises two separate components with distinct 208Pb/204Pb ratios. One component is defined by 208Pb/204Pb ratios >~33.7, implying an old crustal source with κPb greater than coeval mantle (~4.75, crustal Pb source 1 in Figure 2D). A second component, defined by the Norseman gold ores, has 208Pb/204Pb ratios close to the bulk silicate Earth (BSE), implying a κPb close to coeval mantle (~4.0, crustal Pb source 2 in Figure 2D). The scatter of most granites and ores in 208Pb/204Pb versus 206Pb/204Pb space delineates an array between a mantle Pb source and a high-μ, high-κPb crustal source. Although mixing with the Norseman source is not well resolved by the granite data, the presence of highly radiogenic crust in this region is clear in the isotopic map.We estimate crustal 238U/204Pb, 232Th/204Pb, and 232Th/238U using a two-stage Pb isotope evolution model that allows for variable mantle and crustal residence times (Delavault et al., 2016) whereby the ratios are calculated based on the evolution of Pb isotopes in the period between the zircon Hf model age and the crystallization of the granite:orandIn this form, it is clear that the values of µc and Ωc equate to the slope of a straight line connecting the measured initial XPb/204Pb ratio at the time of crystallization (Tc) to the mantle reference curve at the time of crust formation (Ts) in a plot of XPb/204Pb versus eλT, where e is Euler’s constant and λ is the relevant decay constant (Figs. 3E–3G). Crust formation ages were obtained from zircon Hf isotope compositions (Mole et al., 2019) re-calculated using the measured Hf isotope ratios, the 176Lu decay constant of Söderlund et al. (2004), and the depleted mantle parameters of Griffin et al. (2000). Mantle Pb isotope evolution is modeled using the single stage model, after Maltese and Mezger (2020), with µ = 8.42 and κ = 4.03. Using this approach, we calculate an average crustal 238U/204Pb of 11.3 ± 2.1 and 232Th/204Pb of 47.4 ± 10.0, which equates to a 232Th/238U of 4.2 ± 0.3 (Figs. 3E–3G and 4)Recent estimates of crustal 232Th/238U based on a global data set of continental rocks yielded a median value of 3.95 (Wipperfurth et al., 2018). The similarity with modern mantle and primordial 232Th/238U ratios led that study to conclude negligible fractionation of Th and U during either segregation of Earth’s core following accretion, or during crust extraction out of the mantle. Although our results overlap previous estimates for the continental crust, we obtain a crustal κPb ~10% higher than estimates for the bulk silicate Earth on average (Fig. 4). The Yilgarn granite and ore Pb isotope data scatter between a mantle component, defined by some VHMS ores, and a more-radiogenic crustal reservoir. Therefore, the higher average κPb of Archean crust is unlikely to reflect higher mantle Th/U ratios at that time, but rather reflects mixing between a broadly chondritic mantle reservoir and a preexisting Paleoarchean crustal Pb reservoir with 232Th/238U of ~4.7–4.8, requiring ~25% enrichment in Th relative to bulk Earth.The presence of a high-Th/U crustal reservoir demonstrates that fractionation of Th and U accompanied early crust formation and differentiation. As Earth’s atmosphere was devoid of oxygen at this time, both Th and U existed in their 4+ valence state, with any difference in partitioning during mantle melting expressed only at low degrees of partial melting. The presence of ultramafic volcanic rocks (i.e., komatiite) and higher abundance of high-Mg basalts in greenstone belts throughout the Yilgarn craton indicates Earth’s mantle was warmer, and degrees of partial melting were generally higher, than today (Herzberg et al., 2010). Hence, fractionation of Th and U during extraction of crust from the early Archean mantle is unlikely to account for the difference in Pb isotope variability of Archean crust. Geochemical data from modern arc lavas imply that magmatic differentiation processes do not significantly fractionate Th and U (Liu et al., 2019). The apparent Th/U variability of early Archean crust must therefore reflect some other processes that occurred after crust formation. The granites with the highest 208Pb/204Pb ratios predominantly occur within the older western Yilgarn craton and are concentrated in regions with Paleoarchean Hf and Nd model ages (Fig. 2). A spatial analysis of the whole-rock geochemical data from the Yilgarn craton also indicates that one specific variety of potassic granite—the low-Ca, high Ti granites—are high-temperature granites concentrated in regions with old model ages. Both observations suggest that many of the granites in these parts of the craton formed by high-temperature partial melting of old refractory felsic source rocks (Smithies et al., 2023).Th and U may be fractionated during open-system high-temperature metamorphism (Yakymchuk and Brown, 2019). In supra-solidus crust, the distribution of Th and U between a partial melt and the residual solids is strongly influenced by the breakdown and (re)growth of accessory minerals (e.g., zircon, monazite, and apatite; Yakymchuk and Brown, 2019). When present, monazite is most influential, owing to its strong preference for Th over U, although this can vary with melt composition and the behavior of coexisting apatite (Xing et al., 2013; Yakymchuk, 2017). Eoarchean–Paleoarchean granulites exposed in the Narryer terrane in the northwestern parts of the Yilgarn craton underwent partial melting involving zircon and monazite (re)growth as early as 3.3 Ga (Kinny et al., 1988; Iizuka et al., 2010). Thus, the Yilgarn Pb isotope variability can be explained either by re-melting residual Eoarchean–Paleoarchean crust or bulk assimilation/hybridization of mantle-derived melts with this material. Both processes may have occurred during lithospheric thinning and/or underplating associated with Neoarchean basalt-komatiite volcanism.A caveat here is monazite usually grows in low-Ca peraluminous rocks, which are not major components of Archean terranes (Moyen and Laurent, 2018). In mafic systems, which may better reflect early Archean crust, the partitioning of Th and U between melt and rutile could also form high-Th/U melts (Fig. 4B; Klemme et al., 2005; Emo et al., 2023). Although the generation of the high-Th/U signature via earlier melting and/or crystal fractionation processes involving rutile cannot be a priori excluded, a paucity of mafic material in the Narryer terrane (Kemp et al., 2018), and dominance of low-Ca granites in the west Yilgarn (Smithies et al., 2023), suggests the ancient crustal nuclei were sufficiently differentiated to stabilize monazite.If this is true, the formation of a melt-depleted high-Th/U lower crustal residue requires the loss of a complementary low-Th/U silicate melt to the mid-upper crust. However, we find little evidence of this complementary reservoir in the Yilgarn Pb isotope data set. Only a few samples yield κPb values lower than the primordial value of 3.8 (Fig. 4A), indicating low-Th/U material was not overly abundant in the Neoarchean granite sources. Although this may be an artifact of limited sampling in Mesoarchean and Paleoarchean crust, it could also indicate much of this low-Th/U material was lost from the crustal record. Our preferred model requires erosion of U-rich upper crust to explain this. Indeed, the deposition of Mount Narryer and Jack Hills metasediments between 3.2 and 3.0 Ga (Iizuka et al., 2010; Kinny et al., 2022) indicates the basement gneisses were brought from suprasolidus to surface conditions during this time. However, the same outcome could occur via delamination of dense low-Th/U mafic residues formed by earlier crustal differentiation processes (Fig. 4B; Emo et al., 2023). These mechanisms are not mutually exclusive and both could have contributed to the high Th/U signature at different times in craton development. Regardless, it seems clear that the fractionation of Th and U during the early Archean was intimately linked to intra-crustal differentiation processes that stabilized Earth’s continental crust, with accessory minerals playing a crucial role.This work was supported by an Australian Research Council (ARC) Linkage Project (LP180100199) in collaboration with the Geological Survey of Western Australia (GSWA) and Northern Star Resources Ltd. Insightful reviews by Tim Elliott and Balz Kamber significantly improved the manuscript. Thanks to Brian Kennett for providing the AUSREM data, to Noreen Evans, Brad McDonald, and Kai Rankenburg for analytical assistance, and to Marc Norman for editorial handling. Research at Curtin was enabled by AuScope and the Australian Government via funding from the ARC (LE150100013). SPJ and RHS publish with permission from the executive director of the GSWA. DRM publishes with permission from the CEO of Geoscience Australia.","PeriodicalId":12642,"journal":{"name":"Geology","volume":"32 1","pages":""},"PeriodicalIF":4.8000,"publicationDate":"2024-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Geology","FirstCategoryId":"89","ListUrlMain":"https://doi.org/10.1130/g51507.1","RegionNum":1,"RegionCategory":"地球科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"GEOLOGY","Score":null,"Total":0}
引用次数: 0
Abstract
Lead isotopic data imply that thorium and uranium were fractionated from one another in Earth’s early history; however, the origin of this fractionation is poorly understood. We report new in situ Pb isotope data from orthoclase in 144 granites sampled across the Archean Yilgarn craton (Western Australia) to characterize its Pb isotope variability and evolution. Granite Pb isotope compositions reveal three Pb sources, a mantle-derived Pb reservoir and two crustal Pb reservoirs, distinguished by their implied source 232Th/238U (κPb). High-κPb granites reflect sources with high 232Th/238U (~4.7) and are largely co-located with Eoarchean–Paleoarchean crust. The Pb isotope compositions of most granites, and those of volcanic-hosted massive sulfide (VHMS) and gold ores, define a mixing array between a mantle Pb source and a Th-rich Eoarchean–Paleoarchean source. Pb isotope modeling indicates that the high-κPb source rocks experienced Th/U fractionation at ca. 3.3 Ga. As Th/U fractionation in the Yilgarn craton must have occurred before Earth’s atmosphere was oxygenated, subaerial weathering cannot explain the apparent differences in their geochemical behavior. Instead, the high Th/U source reflects Eoarchean–Paleoarchean rocks that experienced prior high-temperature metamorphism, partial melting, and melt loss in the presence of a Th-sequestering mineral like monazite. Archean Pb isotope variability thus has its origins in open-system high-temperature metamorphic processes responsible for the differentiation and stabilization of Earth’s continental crust.Thorium and uranium are highly incompatible trace elements that are partitioned into Earth’s crust over geological time (Galer and O’nions, 1985; Allègre et al., 1986). Being two of the main heat-producing elements in the silicate Earth, understanding their partitioning between different geochemical reservoirs is important for tracking our planet’s thermal evolution and internal differentiation.Thorium has a single valence state (4+) whereas U exists in two valence states (4+ and 6+), with the highly water-soluble hexavalent species dominant under oxidized surface conditions (Zartman and Haines, 1988). Since the Great Oxidation Event (2.5–2.4 Ga), U has preferentially been recycled into the mantle, causing a progressive lowering of the Th/U ratio in the mantle and in rocks derived from it (McCulloch, 1993; Collerson and Kamber, 1999; Elliott et al., 1999; Zartman and Richardson, 2005). However, in the Archean, when Earth’s atmosphere was largely devoid of oxygen, neither mantle melting, fractional crystallization, nor weathering and recycling processes could have fractionated U and Th. Hence, it is thought the geochemical behavior of these elements was identical from the surface down to the upper mantle (Liu et al., 2019). Nevertheless, some lines of evidence show that Th and U were fractionated from one another early in Earth’s history. For example, variability in the 208Pb/204Pb ratios of some Archean rocks and ore minerals require an older Pb source with super-chondritic 232Th/238U (Robertson and Cumming, 1968; Perring and McNaughton, 1992). However, there has been no satisfactory explanation for how Th and U were fractionated from one another this early in Earth’s history.The Yilgarn craton in Western Australia provides an ideal laboratory for investigating the origins of Archean Pb isotope variability. Large volumes of granite were emplaced within a restricted time interval (2.7–2.6 Ga), via reworking of pre-existing crust of variable age (3.8–2.7 Ga; Mole et al., 2019). As the variability in initial Pb isotope composition of granites depends on the 238U/204Pb ratio (μ) and 232Th/238U ratio (κ) of their source rocks and the duration of radioactive decay, any variability in source 232Th/238U will manifest itself in their initial Pb isotope compositions. Analyzing the initial Pb isotope composition of these granites affords the opportunity to probe the deep crustal composition and architecture, and address the origins of Pb isotope variability in ancient crust. Although many rock-forming silicate minerals have non-zero U/Pb ratios, meaning their Pb isotope compositions change over time, one mineral that can yield initial Pb isotope ratios is orthoclase (Gancarz and Wasserburg, 1977).We report new orthoclase laser ablation–inductively coupled plasma–mass spectrometry Pb isotope data from 144 samples of granite feldspar from across the Yilgarn craton. A detailed method description and data tables are provided in the Supplemental Material1.The Yilgarn craton comprises several terranes (Fig. 1). The Narryer terrane occupies the northwest corner of the craton and contains felsic gneisses with protolith ages from 3.73 Ga to 3.37 Ga, and subordinate supracrustal belts (Kinny et al., 1988; Kemp et al., 2018). Together with the South West and Youanmi terranes, they make up the West Yilgarn, which contains evidence for shared 3.00–2.90, 2.80, and 2.73–2.72 Ga magmatism generally characterized by unradiogenic Nd and Hf isotope compositions, indicating an older Paleoarchean source for this region (Mole et al., 2019). The West Yilgarn abuts the Eastern Goldfields Superterrane (EGST) along the Ida fault (Fig. 1). The EGST is dominated by felsic igneous rocks and supracrustal sequences (greenstone belts) formed between 2.72 and 2.66 Ga, representing a period of widespread basalt-komatiite magmatism, which was followed by craton-wide emplacement of tonalite-trondjhemite-granodiorite (TTG) and subsequently K-rich granite, inferred to reflect a widespread lower-crustal melting event (Smithies et al., 2019).Figure 2 shows the Pb isotope ratios of the granite samples along with a compilation of data from volcanic-hosted massive sulfide (VHMS) and Au ores from across the craton, and the terrestrial Pb isotope evolution model of Maltese and Mezger (2020). The range of Pb isotope compositions from the granites is identical to those of the ores (Fig. 2A and 2B), which are both consistent with modeled single-stage paleogeochrons for rocks formed between 2.7 and 2.6 Ga (Figs. 2A and 2C; Table DR1 in the Supplemental Material). The least-radiogenic granites have Pb isotope compositions approaching those of the VHMS ores at Teutonic Bore, which may approximate mantle Pb isotope compositions at that time (Hannington et al., 2005). More than 50% of the samples overlap the initial Pb isotope compositions of Au deposits from the Wiluna-Leonora and Menzies-Kambalda regions, whereas the most-radiogenic samples scatter to higher 206Pb/204Pb and 207Pb/204Pb ratios, like those associated with the Stennet Rocks granite and Au ores from the Norseman area (Figs. 2A and 2C).The spatial variation of granite Pb isotope source model ages using interpolated isotopic maps shows a long-wavelength structure like that observed in zircon initial Hf and whole-rock initial Nd isotopes (Figs. 3A–3C). Specifically, the Youanmi terrane exhibits higher 206Pb/204Pb and 207Pb/204Pb ratios (older source model ages) and Hf model ages as old as 3.8–3.6 Ga (Fig. 3A), indicating granites in these regions sampled old felsic crust with sub-chondritic 176Lu/177Hf and 147Sm/144Nd ratios and μ higher than the bulk Earth model. Across the Ida fault, there is a gradient in both Hf model ages and granite 207Pb/204Pb source ages (Figs. 3A–3C). The EGST granites exhibit less-radiogenic Pb isotope compositions and younger Hf model ages (<2.9 Ga), indicating magmatism in the EGST was derived from source rocks with a greater amount of mantle-derived material. All the isotopic data sets are broadly consistent with the upper mantle velocity structure, which implies a density (and hence age) gradient in subcratonic lithospheric mantle (Fig. 3D; Kennett et al., 2013).Whereas variable 206Pb/204Pb and 207Pb/204Pb ratios reflect mixing between sources with different 238U/204Pb fractionation histories, variation in 208Pb/204Pb ratios reveals sources with different 232Th/238U fractionation histories. A plot of 208Pb/204Pb versus 206Pb/204Pb reveals the high-μ crustal source comprises two separate components with distinct 208Pb/204Pb ratios. One component is defined by 208Pb/204Pb ratios >~33.7, implying an old crustal source with κPb greater than coeval mantle (~4.75, crustal Pb source 1 in Figure 2D). A second component, defined by the Norseman gold ores, has 208Pb/204Pb ratios close to the bulk silicate Earth (BSE), implying a κPb close to coeval mantle (~4.0, crustal Pb source 2 in Figure 2D). The scatter of most granites and ores in 208Pb/204Pb versus 206Pb/204Pb space delineates an array between a mantle Pb source and a high-μ, high-κPb crustal source. Although mixing with the Norseman source is not well resolved by the granite data, the presence of highly radiogenic crust in this region is clear in the isotopic map.We estimate crustal 238U/204Pb, 232Th/204Pb, and 232Th/238U using a two-stage Pb isotope evolution model that allows for variable mantle and crustal residence times (Delavault et al., 2016) whereby the ratios are calculated based on the evolution of Pb isotopes in the period between the zircon Hf model age and the crystallization of the granite:orandIn this form, it is clear that the values of µc and Ωc equate to the slope of a straight line connecting the measured initial XPb/204Pb ratio at the time of crystallization (Tc) to the mantle reference curve at the time of crust formation (Ts) in a plot of XPb/204Pb versus eλT, where e is Euler’s constant and λ is the relevant decay constant (Figs. 3E–3G). Crust formation ages were obtained from zircon Hf isotope compositions (Mole et al., 2019) re-calculated using the measured Hf isotope ratios, the 176Lu decay constant of Söderlund et al. (2004), and the depleted mantle parameters of Griffin et al. (2000). Mantle Pb isotope evolution is modeled using the single stage model, after Maltese and Mezger (2020), with µ = 8.42 and κ = 4.03. Using this approach, we calculate an average crustal 238U/204Pb of 11.3 ± 2.1 and 232Th/204Pb of 47.4 ± 10.0, which equates to a 232Th/238U of 4.2 ± 0.3 (Figs. 3E–3G and 4)Recent estimates of crustal 232Th/238U based on a global data set of continental rocks yielded a median value of 3.95 (Wipperfurth et al., 2018). The similarity with modern mantle and primordial 232Th/238U ratios led that study to conclude negligible fractionation of Th and U during either segregation of Earth’s core following accretion, or during crust extraction out of the mantle. Although our results overlap previous estimates for the continental crust, we obtain a crustal κPb ~10% higher than estimates for the bulk silicate Earth on average (Fig. 4). The Yilgarn granite and ore Pb isotope data scatter between a mantle component, defined by some VHMS ores, and a more-radiogenic crustal reservoir. Therefore, the higher average κPb of Archean crust is unlikely to reflect higher mantle Th/U ratios at that time, but rather reflects mixing between a broadly chondritic mantle reservoir and a preexisting Paleoarchean crustal Pb reservoir with 232Th/238U of ~4.7–4.8, requiring ~25% enrichment in Th relative to bulk Earth.The presence of a high-Th/U crustal reservoir demonstrates that fractionation of Th and U accompanied early crust formation and differentiation. As Earth’s atmosphere was devoid of oxygen at this time, both Th and U existed in their 4+ valence state, with any difference in partitioning during mantle melting expressed only at low degrees of partial melting. The presence of ultramafic volcanic rocks (i.e., komatiite) and higher abundance of high-Mg basalts in greenstone belts throughout the Yilgarn craton indicates Earth’s mantle was warmer, and degrees of partial melting were generally higher, than today (Herzberg et al., 2010). Hence, fractionation of Th and U during extraction of crust from the early Archean mantle is unlikely to account for the difference in Pb isotope variability of Archean crust. Geochemical data from modern arc lavas imply that magmatic differentiation processes do not significantly fractionate Th and U (Liu et al., 2019). The apparent Th/U variability of early Archean crust must therefore reflect some other processes that occurred after crust formation. The granites with the highest 208Pb/204Pb ratios predominantly occur within the older western Yilgarn craton and are concentrated in regions with Paleoarchean Hf and Nd model ages (Fig. 2). A spatial analysis of the whole-rock geochemical data from the Yilgarn craton also indicates that one specific variety of potassic granite—the low-Ca, high Ti granites—are high-temperature granites concentrated in regions with old model ages. Both observations suggest that many of the granites in these parts of the craton formed by high-temperature partial melting of old refractory felsic source rocks (Smithies et al., 2023).Th and U may be fractionated during open-system high-temperature metamorphism (Yakymchuk and Brown, 2019). In supra-solidus crust, the distribution of Th and U between a partial melt and the residual solids is strongly influenced by the breakdown and (re)growth of accessory minerals (e.g., zircon, monazite, and apatite; Yakymchuk and Brown, 2019). When present, monazite is most influential, owing to its strong preference for Th over U, although this can vary with melt composition and the behavior of coexisting apatite (Xing et al., 2013; Yakymchuk, 2017). Eoarchean–Paleoarchean granulites exposed in the Narryer terrane in the northwestern parts of the Yilgarn craton underwent partial melting involving zircon and monazite (re)growth as early as 3.3 Ga (Kinny et al., 1988; Iizuka et al., 2010). Thus, the Yilgarn Pb isotope variability can be explained either by re-melting residual Eoarchean–Paleoarchean crust or bulk assimilation/hybridization of mantle-derived melts with this material. Both processes may have occurred during lithospheric thinning and/or underplating associated with Neoarchean basalt-komatiite volcanism.A caveat here is monazite usually grows in low-Ca peraluminous rocks, which are not major components of Archean terranes (Moyen and Laurent, 2018). In mafic systems, which may better reflect early Archean crust, the partitioning of Th and U between melt and rutile could also form high-Th/U melts (Fig. 4B; Klemme et al., 2005; Emo et al., 2023). Although the generation of the high-Th/U signature via earlier melting and/or crystal fractionation processes involving rutile cannot be a priori excluded, a paucity of mafic material in the Narryer terrane (Kemp et al., 2018), and dominance of low-Ca granites in the west Yilgarn (Smithies et al., 2023), suggests the ancient crustal nuclei were sufficiently differentiated to stabilize monazite.If this is true, the formation of a melt-depleted high-Th/U lower crustal residue requires the loss of a complementary low-Th/U silicate melt to the mid-upper crust. However, we find little evidence of this complementary reservoir in the Yilgarn Pb isotope data set. Only a few samples yield κPb values lower than the primordial value of 3.8 (Fig. 4A), indicating low-Th/U material was not overly abundant in the Neoarchean granite sources. Although this may be an artifact of limited sampling in Mesoarchean and Paleoarchean crust, it could also indicate much of this low-Th/U material was lost from the crustal record. Our preferred model requires erosion of U-rich upper crust to explain this. Indeed, the deposition of Mount Narryer and Jack Hills metasediments between 3.2 and 3.0 Ga (Iizuka et al., 2010; Kinny et al., 2022) indicates the basement gneisses were brought from suprasolidus to surface conditions during this time. However, the same outcome could occur via delamination of dense low-Th/U mafic residues formed by earlier crustal differentiation processes (Fig. 4B; Emo et al., 2023). These mechanisms are not mutually exclusive and both could have contributed to the high Th/U signature at different times in craton development. Regardless, it seems clear that the fractionation of Th and U during the early Archean was intimately linked to intra-crustal differentiation processes that stabilized Earth’s continental crust, with accessory minerals playing a crucial role.This work was supported by an Australian Research Council (ARC) Linkage Project (LP180100199) in collaboration with the Geological Survey of Western Australia (GSWA) and Northern Star Resources Ltd. Insightful reviews by Tim Elliott and Balz Kamber significantly improved the manuscript. Thanks to Brian Kennett for providing the AUSREM data, to Noreen Evans, Brad McDonald, and Kai Rankenburg for analytical assistance, and to Marc Norman for editorial handling. Research at Curtin was enabled by AuScope and the Australian Government via funding from the ARC (LE150100013). SPJ and RHS publish with permission from the executive director of the GSWA. DRM publishes with permission from the CEO of Geoscience Australia.
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Published since 1973, Geology features rapid publication of about 23 refereed short (four-page) papers each month. Articles cover all earth-science disciplines and include new investigations and provocative topics. Professional geologists and university-level students in the earth sciences use this widely read journal to keep up with scientific research trends. The online forum section facilitates author-reader dialog. Includes color and occasional large-format illustrations on oversized loose inserts.