Contributions to Mineralogy and Petrology

, Volume 166, Issue 4, pp 1253–1268 | Cite as

Diversity of primary CL textures in quartz from porphyry environments: implication for origin of quartz eyes

  • O. V. Vasyukova
  • V. S. Kamenetsky
  • K. Goemann
  • P. Davidson
Original Paper
First Online:
Received:
Accepted:

Abstract

Porphyry-style mineralization is related to the intrusion and crystallization of small stocks, which can be of different compositions (from intermediate to felsic) and can intrude into different host rocks (from magmatic to sedimentary). We used cathodoluminescence and electron probe microanalysis to study the internal textures of more than 300 quartz eyes from six porphyry deposits, Panguna (Papua New Guinea), Far Southeast porphyry (Philippines), Batu Hijau (Indonesia), Antapaccay (Peru), Rio Blanco (Chile) and Climax (USA). Significant diversity of the internal textures in quartz eyes was revealed, sometimes even within a single sample. Quartz grains with Ti-rich cores surrounded by Ti-poor mantles were found next to the grains showing the opposite Ti distribution or only slight Ti fluctuations.We propose that diversity of the internal patterns in quartz eyes can actually reflect in situ crystallization history, and that prolonged crystallization after magma emplacement under conditions of continuous cooling can account for the observed features of internal textures. Formation of quartz eyes begins at high temperatures with crystallization of high titanium Quartz 1, which as the melt becomes more and more evolved and cooler, is overgrown by low Ti Quartz 2. Subsequent fluid exsolution brings about dramatic change in the melt composition: OH , alkalis and other Cl-complexed elements partition into the fluid phase, whereas Ti stays in the melt, contributing to a rapid increase in Ti activity. Separation of the fluid and its further cooling causes disequilibrium in the system, and the Quartz 2 becomes partially resorbed. Exsolution of the fluid gradually builds up the pressure until it exceeds the yield strength of the host rocks and they then fracture. This pressure release most likely triggers crystallization of Quartz 3, which is higher in Ti than Quartz 2 because Ti activity in the melt is higher and pressure of crystallization is lower. As a result of the reaction between the exsolved fluid and quartz a new phase, a so called ‘heavy fluid’ forms. From this phase Quartz 4 crystallizes. This phase has extremely high metal-carrying capacity, and may give a rise to mineralizing fluids. Finally, on the brink of the subsolidus stage, groundmass quartz crystallizes. Prolonged crystallization under conditions of continuous cooling accounts better for the diversity of CL textures than crystallization in different parts of a deep magma chamber. It is also in a better agreement with the existing model for formation of porphyry-style deposits.

Keywords

Cathodoluminescence Quartz eyes Porphyry deposits 
This is a preview of subscription content, log in to check access.

References

  1. Agangi A, McPhie J, Kamenetsky VS (2011) Magma chamber dynamics in a silicic LIP revealed by quartz: the Mesoproterozoic Gawler Range Volcanics. Lithos 126(1–2):68–83. doi: 10.1016/j.lithos.2011.06.005 CrossRefGoogle Scholar
  2. Burnham CW (1979) Magmas and hydrothermal fluids. In: Barnes HL (ed) Geochemistry of hydrothermal ore deposits, 3rd edn. Wiley, New York, pp 63–123Google Scholar
  3. Chang ZS, Meinert LD (2004) The magmatic-hydrothermal transition—evidence from quartz phenocryst textures and endoskarn abundance in Cu-Zn skarns at the Empire Mine, Idaho. USA. Chem Geol 210(1–4):149–171. doi: 10.1016/j.chemgeo.2004.06.018 CrossRefGoogle Scholar
  4. Cloos M (2001) Bubbling magma chambers, cupolas, and porphyry copper deposits. Int Geol Rev 43(4):285–311CrossRefGoogle Scholar
  5. Fulignati P, Kamenetsky VS, Marianelli P, Sbrana A, Meffre S (2011) First insights on the metallogenic signature of magmatic fluids exsolved from the active magma chamber of Vesuvius (AD 79 “Pompei” eruption). J Volcanol Geoth Res 200(3–4):223–233. doi: 10.1016/j.jvolgeores.2010.12.015 CrossRefGoogle Scholar
  6. Götze J (2009) Chemistry, textures and physical properties of quartz—geological interpretation and technical application. Mineral Mag 73(4):645–671. doi: 10.1180/minmag.2009.073.4.645 CrossRefGoogle Scholar
  7. Götze J, Plötze M, Habermann D (2001) Origin, spectral characteristics and practical applications of the cathodoluminescence (CL) of quartz—a review. Mineral Petrol 71:225–250CrossRefGoogle Scholar
  8. Götze J, Plötze M, Grafer T, Hallbauer DK, Bray CJ (2004) Trace element incorporation into quartz: a combined study by ICP-MS, electron spin resonance, cathodoluminescence, capillary ion analysis, and gas chromatography. Geochim Cosmochim Acta 68(18):3741–3759CrossRefGoogle Scholar
  9. Gustafson LB (1978) Some major factors of porphyry copper genesis. Econ Geol 73(5):600–607CrossRefGoogle Scholar
  10. Harris AC, Kamenetsky VS, White NC, Steele DA (2004) Volatile phase separation in silicic magmas at Bajo de la Alumbrera porphyry Cu-Au deposit, NW Argentina. Resour Geol 54(3):341–356Google Scholar
  11. Kamenetsky VS, Kamenetsky MB (2010) Magmatic fluids immiscible with silicate melts: examples from inclusions in phenocrysts and glasses, and implications for magma evolution and metal transport. Geofluids 10(1–2):293–311. doi: 10.1111/j.1468-8123.2009.00272.x Google Scholar
  12. Kotel’nikova ZA, Kotel’nikov AR (2010a) Experimental study of heterogeneous fluid equilibria in silicate-salt-water systems. Geol Ore Depos 52(2):154–166. doi: 10.1134/S1075701510020042 CrossRefGoogle Scholar
  13. Kotel’nikova ZA, Kotel’nikov AR (2010b) Immiscibility in sulfate-bearing fluid systems at high temperatures and pressures. Geochem Int 48(4):381–389. doi: 10.1134/S0016702910040063 CrossRefGoogle Scholar
  14. MacLellan HE, Trembath LT (1991) The role of quartz crystallization in the development and preservation of igneous texture in granitic-rocks—experimental-evidence at 1-kbar. Am Mineral 76(7–8):1291–1305Google Scholar
  15. McGuire AV, Francis CA, Dyar MD (1992) Mineral standards for electron-microprobe analysis of oxygen. Am Mineral 77(9–10):1087–1091Google Scholar
  16. Müller A, Breiter K, Seltmann R, Pecskay Z (2005) Quartz and feldspar zoning in the eastern Erzgebirge volcano-plutonic complex (Germany, Czech Republic): evidence of multiple magma mixing. Lithos 80(1–4):201–227. doi: 10.1016/j.lithos.2004.05.011 CrossRefGoogle Scholar
  17. Müller A, Herrington R, Armstrong R, Seltmann R, Kirwin DJ, Stenina NG, Kronz A (2010a) Trace elements and cathodoluminescence of quartz in stockwork veins of Mongolian porphyry-style deposits. Miner Depos 45(7):707–727. doi: 10.1007/s00126-010-0302-y CrossRefGoogle Scholar
  18. Müller A, van den Kerkhof AM, Behr HJ, Kronz A, Koch-Müller M (2010b) The evolution of late-Hercynian granites and rhyolites documented by quartz—a review. Earth Environ Sci Trans R Soc Edinb 100:185–204. doi: 10.1017/S1755691009016144 CrossRefGoogle Scholar
  19. Peretyazhko IS, Smirnov SZ, Kotel’nikov AR, Kotel’nikova ZA (2010) Experimental study of the system H3BO3-NaF-SiO2-H2O at 350–800 degrees C and 1–2 kbar by the method of synthetic fluid inclusions. Russ Geol Geophys 51(4):349–368. doi: 10.1016/j.rgg.2010.03.003 CrossRefGoogle Scholar
  20. Roedder E (1984) Fluid Inclusions. Rev Mineral 12:1–646CrossRefGoogle Scholar
  21. Rusk BG, Lowers HA, Reed MH (2008) Trace elements in hydrothermal quartz: relationships to cathodoluminescent textures and insights into vein formation. Geology 36(7):547–550. doi: 10.1130/G24580a.1 CrossRefGoogle Scholar
  22. Shane P, Smith VC, Nairn I (2008) Millennial timescale resolution of rhyolite magma recharge at Tarawera volcano: insights from quartz chemistry and melt inclusions. Contrib Mineral Petrol 156(3):397–411. doi: 10.1007/s00410-008-0292-2 CrossRefGoogle Scholar
  23. Sinclair WD (2007) Porphyry deposits. In: Goodfellow WD (ed) Mineral deposits of Canada: A synthesis of major deposit-types, district metallogeny, the evolution of geological provinces, and exploration methods: geological association of Canada, Mineral Deposits Division, vol Special Publication No. 5. pp 223–243Google Scholar
  24. Smirnov SZ, Thomas VG, Kamenetsky VS, Kozmenko OA, Large RR (2012) Hydrosilicate liquids in the system Na2O-SiO2-H2O with NaF, NaCl and Ta: evaluation of their role in ore and mineral formation at high and T and P. Petrology 20(3):271–285. doi: 10.1134/S0869591112020063 CrossRefGoogle Scholar
  25. Stevens-Kalceff MA (2009) Cathodoluminescence microcharacterization of point defects in alpha-quartz. Mineral Mag 73(4):585–605. doi: 10.1180/minmag.2009.073.4.585 CrossRefGoogle Scholar
  26. Stevens-Kalceff MA, Phillips MR (1995) Cathodoluminescence microcharacterization of the defect structure of quartz. Phys Rev B 52(5):3122–3134CrossRefGoogle Scholar
  27. Thomas R, Davidson P (2008) Water and melt–melt immiscibility, the essential component in the formation of pegmatities; evidence from melt inclusions. Z Geol Wiss 36(6):347–364Google Scholar
  28. Thomas JB, Watson EB, Spear FS, Shemella PT, Nayak SK, Lanzirotti A (2010a) TitaniQ under pressure: the effect of pressure and temperature on the solubility of Ti in quartz. Contrib Mineral Petrol 160(5):743–759. doi: 10.1007/s00410-010-0505-3 CrossRefGoogle Scholar
  29. Thomas VG, Smirnov SZ, Kamenetsky VS, KO A (2010b) Formation of hydrosilicate liquids in the system Na2O (± K2O) − SiO2 (± Al2O3)–H2O and their ability to concentrate some elements (on the basis of experimental data). Paper presented at the Asian current research on fluid inclusions. Novosibirsk, RussiaGoogle Scholar
  30. Vasyukova OV, Goemann K, Kamenetsky VS, MacRae CM, Wilson NC (2013) Cathodoluminescence properties of quartz eyes from porphyry-type deposits: implications for the origin of quartz. Am Mineral 98:98–109CrossRefGoogle Scholar
  31. Veksler IV (2004) Liquid immiscibility and its role at the magmatic-hydrothermal transition: a summary of experimental studies. Chem Geol 210(1–4):7–31. doi: 10.1016/j.chemgeo.2004.06.002 CrossRefGoogle Scholar
  32. Wark DA, Watson EB (2006) TitaniQ: a titanium-in-quartz geothermometer. Contrib Mineral Petrol 152:743–754CrossRefGoogle Scholar
  33. Wark DA, Spear FS, Cherniak DJ, Watson EB (2007) Pre-eruption recharge of the Bishop magma system. Geology 35(3):235–238CrossRefGoogle Scholar
  34. Wiebe RA, Wark DA, Hawkins DP (2007) Insights from quartz cathodoluminescence zoning into crystallization of the Vinalhaven granite, coastal Maine. Contrib Mineral Petrol 154:439–453CrossRefGoogle Scholar
  35. Wilkinson JJ (2001) Fluid inclusions in hydrothermal ore deposits. Lithos 55(1–4):229–272CrossRefGoogle Scholar
  36. Wilkinson JJ, Nolan J, Rankin AH (1996) Silicothermal fluid: a novel medium for mass transport in the lithosphere. Geology 24(12):1059–1062CrossRefGoogle Scholar

Copyright information

© Springer-Verlag Berlin Heidelberg 2013

Authors and Affiliations

  • O. V. Vasyukova
    • 1
    • 3
  • V. S. Kamenetsky
    • 1
  • K. Goemann
    • 2
  • P. Davidson
    • 1
  1. 1.ARC Centre of Excellence in Ore Deposits and School of Earth SciencesUniversity of TasmaniaHobartAustralia
  2. 2.Central Science LaboratoryUniversity of TasmaniaHobartAustralia
  3. 3.Earth and Planetary SciencesMcGill UniversityMontrealCanada

Personalised recommendations