Abstract
Extraordinarily high Pb content in K-feldspar and plagioclase has been found contiguous to monazite in two occurrences in the ultrahigh-temperature Napier Complex of Antarctica. Monazite shows a variety of textures and compositions. In a garnet-sillimanite-orthopyroxene paragneiss at Mount Pardoe (Amundsen Bay), grains range 80–150 μm across and are anhedral; two grains are Th- and Si-dominant. In pods that crystallized from anatectic melts at 2500 Ma at Zircon Point, Casey Bay, monazite grains range 0.05 mm–1 cm in length and are highly variable in texture. The coarsest grains (>0.7 cm) are skeletal and euhedral, whereas the smallest grains are anhedral and associated with fine- to medium-grained quartz, K-feldspar, plagioclase, garnet, sillimanite and rutile in aggregates that form interstitial veinlets interpreted to be a second generation of anatexis during an event at 1100 Ma. The huttonite component (ThSiO4) reaches 30 mole% in the cores of the coarsest skeletal grains, whereas other grains, particularly smaller ones, show complex and irregular zoning in Th and U. The latter zoning is attributed to dissolution-reprecipitation, which also resulted in complete Pb loss during the 1100 Ma event. In the paragneiss at Mount Pardoe, K-feldspar and myrmekitic plagioclase (An16) are found in a 70–80 μm band between monazite and orthopyroxene and contain up to 12.7 wt.% and 2.7 wt.% PbO, respectively, corresponding to 18.5% and 3.4% PbAl2Si2O8 component, respectively. Cathodoluminescence of both feldspars increases with distance from a nearby monazite grain and is not correlated with Pb content. Incorporation of Pb in K-feldspar and plagioclase could be a result of diffusion, even though the monazite adjacent to feldspar apparently lost little Pb, i.e., Pb could have been transported by fluid from the Th-rich grains, which did lose Pb. In contrast to the paragneiss, cathodoluminescence correlates with Pb content of K-feldspar in aureoles surrounding skeletal monazite grains 0.7–1 cm across in anatectic pods at Zircon Point. Pb content of K-feldspar decreases monotonically to near detection limits within several millimetres of monazite grains; the greatest PbO concentration is attained in K-feldspar inliers and embayments in monazite, 8.8 wt.%, corresponding to 11.7% PbAl2Si2O8 component. Fine-grained quartz in the K-feldspar suggests that the mechanism for Pb incorporation involved breakdown of feldspar: Pb2+ + 2(K,Na)AlSi3O8 → PbAl2Si2O8 + 4SiO2 + 2(K,Na)+ . The smooth decrease of Pb in the aureoles is not characteristic of dissolution-reprecipitation, which is characterized by abrupt changes of composition, and it seems more likely that Pb was incorporated in K-feldspar by diffusion at 1100 Ma. We suggest a model whereby fluid introduced during the 1100 Ma event flowed along grain boundaries and penetrated mineral grains. Temperatures were sufficiently high, i.e., 700°C, assuming burial in the mid-crust, for the fluid to induce localized melting of quartzofeldspathic matrix of the anatectic pods. Loss of radiogenic Pb was complete. Some penetration of K-feldspar by aqueous fluid is suggested by the presence of scattered galena specks and by rays of turbidity emanating from monazite. Aqueous fluid or water-rich granitic melt may have mediated the diffusion of Pb in feldspar, but it did not cause dissolution-reprecipitation. Although Pb was mobilized by aqueous fluid or water-rich granitic melt, it was not entirely flushed from the immediate vicinity of the monazite, but nearly half was incorporated in adjacent feldspar. Fluid activity that could cause Pb loss in monazite does not always leave an obvious trace, i.e., hydrous minerals, such as sericite, are very sparse, and biotite is absent in the anatectic pods at Zircon Point. Nonetheless, electron microprobe dating of monazite from the pods could not detect the 2500 Ma age of original crystallization determined by isotopic dating.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Asami M, Suzuki K, Grew ES (2002) Chemical Th–U–total Pb dating by electron microprobe analysis of monazite, xenotime and zircon from the Archean Napier Complex, East Antarctica: evidence for ultra-high-temperature metamorphism at 2400 Ma. Precambrian Res 114:249–275
Baro J, Sempau J, Fernandez-Varea JM, Salvat C (1995) PENELOPE—An algorithm for Monte-Carlo simulation of the penetration and energy-loss of electrons and positrons in matter. Nucl Met Res Phys B Beam Interact Mater Atoms 100:31–46
Bea F (1996) Residence of REE, Y, Th and U in granites and crustal protoliths; implications for the chemistry of crustal melts. J Petrol 37:521–552
Black LP, James PR, Harley SL (1983) Geochronology and geological evolution of metamorphic rocks in the Field Islands area, East Antarctica. J Metamorph Geol 1:277–303
Black LP, Fitzgerald JD, Harley SL (1984) Pb isotopic composition, colour, and microstructure of monazites from a polymetamorphic rock in Antarctica. Contrib Mineral Petrol 85:141–148
Carson CJ, Ague JJ, Coath CD (2002) U–Pb geochronology from Tonagh Island, East Antarctica: implications for the timing of ultra-high temperature metamorphism of the Napier Complex. Precambrian Res 116:237–263
Čech F, Mísař Z, Povondra P (1971) A green lead-containing orthoclase. Tschermaks Mineral Petrol Mitt 15:213–231
Cherniak DJ (1995) Diffusion of lead in plagioclase and K-feldspar: an investigation using Rutherford backscattering and resonant nuclear reaction analysis. Contrib Mineral Petrol 120:358–371
Cherniak DJ, Watson EB, Grove M, Harrison TM (2004) Pb diffusion in monazite: a combined RBS/SIMS study. Geochim Cosmochim Ac 68:829–840
Christy AG, Gatedal K (2005) Extremely Pb-rich rock-forming silicates including a beryllian scapolite and associated minerals in a skarn from Långban, Värmland, Sweden. Mineral Mag 69:995–1018
Doe BR, Tilling RI (1967) The distribution of lead between coexisting K-feldspar and plagioclase. Am Mineral 52:805–816
Ewart A, Griffin WL (1994) Application of proton-microprobe data to trace-element partitioning in volcanic rocks. Chem Geol 117:251–284
Förster H-J (1998) The chemical composition of REE-Y-Th-U-rich accessory minerals in peraluminous granites of the Erzgebirge-Fichtelgebirge region, Germany, Part I: the monazite-(Ce)-brabantite solid solution series. Am Mineral 83:259–272
Gardés E, Jaoul O, Montel J-M, Seydoux-Guillaume A-M, Wirth R (2006) Pb diffusion in monazite: An experimental study of Pb2+ + Th4+ ⇔ 2Nd3+ interdiffusion. Geochim Cosmochim Ac 70:2325–2336
Goncalves P, Williams ML, Jercinovic MJ (2005) Electron-microprobe age mapping of monazite. Am Mineral 90:578–585
Grew ES (1981) Surinamite, taaffeite, and beryllian sapphirine from pegmatites in granulite-facies rocks in Casey Bay, Enderby Land, Antarctica: Am Mineral 66:1022–1033
Grew ES (1998) Boron and beryllium minerals in granulite-facies pegmatites and implications of beryllium pegmatites for the origin and evolution of the Archean Napier Complex of East Antarctica. Mem Nat Inst Polar Res Spec Issue 53:74–92
Grew ES, Manton WI, Sandiford M (1982) Geochronologic studies in East Antarctica: age of pegmatites in Casey Bay, Enderby Land. Antarctic J US 17(5):1–2
Grew ES, Yates MG, Shearer CK, Hagerty JJ, Sheraton JW, Sandiford M (2006) Beryllium and other trace elements in paragneisses and anatectic veins of the ultrahigh-temperature Napier Complex, Enderby Land, East Antarctica: the role of sapphirine. J Petrol 47:859–882
Harley S (1998). On the occurrence and characterization of ultrahigh-temperature crustal metamorphism. In: Treloar PJ, O’Brien PJ (eds) What drives metamorphism and metamorphic reactions? Geological Society, London, Special Publications. vol. 138, pp 81–107
Harley SL, Kinny PD, Snape I, Black LP (2001) Zircon chemistry and the definition of events in Archaean granulite terrains. Record—Austral Geol Surv Org Report 2001/37:511–513
Harlov DE, Hetherington CJ (2007) Partial replacement of homogeneous monazite by monazite enriched in the ThSiO4–CaTh(PO4)2 component: nature and experiment. Frontiers in Mineral Sciences 2007: Programme and Abstracts, 248–249
Harlov DE, Wirth R, Hetherington CJ (2006) Replacement of monazite by a huttonite component: nature and experiment. Geochim Cosmochim Acta 70(18): Supplement 1, A231
Harrison TM, Catlos EJ, Montel J-M (2002) U–Th–Pb dating of phosphate minerals. In: Kohn MJ, Rakovan J, Hughes JM (eds) Phosphates: geochemical, geobiological and materials importance. Mineral Soc Am, Washington, DC, Reviews Mineral Geochem, 48, pp 523–558
Hokada T, Misawa K, Yokoyama K, Shiraishi K, Yamaguchi A (2004) SHRIMP and electron microprobe chronology of UHT metamorphism in the Napier Complex, East Antarctica: implications for zircon growth at >1000°C. Contrib Mineral Petrol 147:1–20
Jercinovic MJ, Williams ML (2005) Analytical perils (and progress) in electron microprobe trace element analysis applied to geochronology: Background acquisition, interferences, and beam irradiation effects. Am Mineral 90:526–546
Kelly NM, Harley SL (2005) An integrated microtextural and chemical approach to zircon geochronology: refining the Archaean history of the Napier Complex, East Antarctica. Contrib Mineral Petrol 149:57–84
Kucha H (1985) Feldspar, clay, organic and carbonate receptors of heavy metals in Zechstein deposits (Kupferschiefer-type), Poland. Institution of Mining and Metallurgy, Trans, Sect B Applied Earth Sci 94:B133–B146
Leeman WP (1979) Partitioning of Pb between volcanic glass and coexisting sanidine and plagioclase feldspars. Geochim Cosmochim Acta 43:171–175
Linthout K (2007) Tripartite division of the system 2REEPO4–CaTh(PO4)2–2ThSiO4, discreditation of brabantite, and recognition of cheralite as the name for members dominated by CaTh(PO4)2. Can Mineral 45:503–508
McDonough WF, Sun S-S (1995) The composition of the Earth. Chem Geol 120:223–253
McFarlane CRM, Harrison TM (2006) Pb-diffusion in monazite: Constraints from a high-T contact aureole setting. Earth Planet Sci Lett 250:376–384
Merlet C (1994) An accurate computer correction program for quantitative electron microprobe analysis. Mikrochim Acta 114:363–376
Montel J-M, Foret S, Veschambre M, Nicollet C, Provost A (1996) Electron microprobe dating of monazite. Chem Geol 131:37–53
Montel J-M, Kornprobst J, Vielzeuf D (2000) Preservation of old U–Th–Pb ages in shielded monazite: example from the Beni Bousera Hercynian kinzigites (Morocco). J Metamorphic Geol 18:335–342
Murakami H, Takashima I, Nishida N (2000) Solubility and behavior of lead in green orthoclase (amazonite) from Broken Hill, New South Wales, Australia. J Mineral Petrol Econ Geol 95:71–84
Nash WP, Crecraft HR (1985) Partition coefficients for trace elements in silicic magmas. Geochim Cosmochim Ac 49:2309–2322
Putnis A (2002) Mineral replacement reactions: from macroscopic observations to microscopic mechanisms. Mineral Mag 66(5):689–708
Putnis A, Hinrichs R, Putnis CV, Golla-Schindler U, Collins LG (2007) Hematite in porous red-clouded feldspars: Evidence of large-scale crustal fluid–rock interaction. Lithos 95:10–18
Pyle JM, Spear FS, Wark DA (2002) Electron microprobe analysis of REE in apatite, monazite and xenotime: protocols and pitfalls. In: Kohn MJ, Rakovan J, Hughes JM (eds) Phosphates: geochemical, geobiological and materials importance. vol 48. Mineral Soc Am, Washington, DC, Reviews Mineral Geochem, pp 337–362
Sandiford M (1985) The metamorphic evolution of granulites at Fyfe Hills; implications for Archaean crustal thickness in Enderby Land, Antarctica. J Metamorphic Geol 3:155–178
Sandiford M, Wilson CJL (1984) The structural evolution of the Fyfe Hills–Khmara Bay region, Enderby Land, East Antarctica. Austral J Earth Sci 31:403–426
Scherrer NC, Engi M, Gnos E, Jacob V, Leichti A (2000) Monazite analysis; from sample preparation to microprobe age dating and REE quantification. Schweiz Mineral Petrogr Mitt 80:93–105
Seydoux-Guillaume A-M, Wirth R, Nasdala L, Gottschalk M, Montel J-M, Heinrich W (2002a) An XRD, TEM and Raman study of experimentally annealed natural monazite. Phys Chem Miner 29:240–253
Seydoux-Guillaume A-M, Paquette JL, Wiedenbeck M, Montel J-M, Heinrich W (2002b) Experimental resetting of the U–Th–Pb systems in monazite. Chem Geol 191:165–181
Seydoux-Guillaume A-M, Goncalves P, Wirth R, Deutsch A (2003) Transmission electron microscope study of polyphase and discordant monazites: Site-specific specimen preparation using the focused ion beam technique. Geology 31:973–976
Seydoux-Guillaume A-M, Wirth R, Deutsch A, Schärer U (2004) Microstructure of 24–1928 Ma concordant monazites; implications for geochronology and nuclear waste deposits. Geochim Cosmochim Ac 68:2517–2527
Sheraton JW, Tingey RJ, Black LP, Offe LA, Ellis DJ (1987) Geology of an unusual Precambrian high-grade metamorphic terrane—Enderby Land and western Kemp Land, Antarctica. Austral Bur Mineral Resources Geol Geophys Bull 223:1–51
Smith HA, Giletti BJ (1997) Lead diffusion in monazite. Geochim Cosmochim Ac 61:1047–1055
Sokolov M, Martin RF (2006) Plumbian microcline and the Pb-dominant analog of celsian included in amazonitic K-feldspar, Mount Ploskaya, Kola Peninsula, Russia. 19th General Meeting of the International Mineralogical Association, Program & Abstracts, p 145
Stevenson RK, Martin RF (1986) Implications of the presence of amazonite in the Broken Hill and Geco metamorphosed sulfide deposits. Can Mineral 24:729–745
Stevenson RK, Martin RF (1988) Amazonitic K-feldspar in granodiorite at Portman Lake, Northwest Territories: Indications of low f(O2), low f(S2), and rapid uplift. Can Mineral 26:1037–1048
Teufel S, Heinrich W (1997) Partial resetting of the U–Pb isotope system in monazite through hydrothermal experiments: an SEM and U–Pb isotope study. Chem Geol 137:273–281
Vernon RH (2004) A practical guide to rock microstructure. Cambridge University Press, Cambridge, UK
Walker FDL, Lee MR, Parsons I (1995) Micropores and micropermeable texture in alkali feldspars: geochemical and geophysical implications. Mineral Mag 59:505–534
Williams ML, Jercinovic MJ (2002) Microprobe monazite geochronology: putting absolute time into microstructural analysis. J Struct Geol 24:1013–1028
Acknowledgments
We thank Michael Jercinovic, Michael Williams, Callum Hetherington and an anonymous reviewer for constructive comments of an earlier draft of the manuscript. Discussions with Daniel Harlov were particularly illuminating. We thank John Fournelle for performing several PENELOPE Monte Carlo simulations. ESG and CJLW thank the Australian National Antarctic Research Expedition for logistic support during the 1979–1980 summer field season, and ESG thanks the 40th Japanese Antarctic Research Expedition for logistic support during the 1998–1999 summer field season. ESG’s and MGY’s research was supported by U.S. National Science Foundation grants OPP-00887235, OPP-0228842 and MRI-0116235 to the University of Maine.
Author information
Authors and Affiliations
Corresponding author
Additional information
Communicated by T.L. Grove.
Rights and permissions
About this article
Cite this article
Grew, E.S., Yates, M.G. & Wilson, C.J.L. Aureoles of Pb(II)-enriched feldspar around monazite in paragneiss and anatectic pods of the Napier Complex, Enderby Land, East Antarctica: the roles of dissolution-reprecipitation and diffusion. Contrib Mineral Petrol 155, 363–378 (2008). https://doi.org/10.1007/s00410-007-0247-z
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00410-007-0247-z