Experimental determination of calcite solubility in H2O-NaCl solutions at deep crust/ upper mantle pressures and temperatures: Implications for metasomatic processes in shear zones

Abstract The solubility of calcite in NaCl-H2O solutions was measured at 600-900 °C, 10 kbar, at NaCl concentrations ranging from dilute to near halite saturation, and at 6-14 kbar, 700 °C, in 30 mol% NaCl solutions. Solubility was determined from the weight loss of cleavage rhombs of a pure natural calcite after experiments of 1/2 to 6 days in a piston-cylinder apparatus with NaCl-graphite furnaces. CaCO3 molality (mCaCO₃) increases greatly with NaCl mole fraction (XNaCl): at 800 °C and 10 kbar, mCaCO₃ increases from ~0.1 in pure H2O to near 4.0 at halite saturation (XNaCl ~ 0.6). There is also a large temperature effect at 10 kbar, with mCaCO₃ increasing from 0.25 at 600 °C to 3.0 at 900 °C at XNaCl = 0.3. There is only a 20% increase with increasing pressure between 6 and 14 kbar at 700 °C and XNaCl = 0.3. Melting to a carbonate-rich liquid was inferred at 900 °C, 10 kbar, from XNaCl of 0 to 0.2. The composition, temperature, and pressure dependence of mCaCO₃ are described by: mCaCO₃ = [-0.051 + 1.65 × 10-4 T + X2NaCl exp(-3.071 + 4.749 × 10-6T2)] (0.76 + 0.024P) with T in Kelvins and P in kbar. The predicted increase of calcite solubility with salinity and temperature is so great that critical mixing of NaCl-rich hydrous carbonate liquid and CaCO3-rich saline solution is probable at 10 kbar near 1000 °C and XNaCl ~ 0.4. The experimental results suggest a genetic mechanism for the enigmatic carbonated shear zones, such as the Attur Valley of southern India, where crustal rocks have been replaced by up to 20% by calcite and ankerite with mantle-like stable-isotope signatures. The high CaCO3 carrying capacity of concentrated alkali-chloride solutions, together with the drastic decrease in solubility between 1000 and 700 °C, plausibly account for large-scale emplacement of mantle-derived carbonate from concentrated chloride-carbonate solutions (or hydrosaline magmas) formed as immiscible fluids in the late stages of alkalic magmatism. Such solutions may also mobilize sulfate and phosphate minerals, which would have important consequences for redistribution of incompatible and heat-producing elements in the crust.

[1]  O. Navon,et al.  Brine inclusions in diamonds: a new upper mantle fluid , 2001 .

[2]  C. Manning,et al.  Quartz solubility in H2O-NaCl and H2O-CO2 solutions at deep crust-upper mantle pressures and temperatures: 2–15 kbar and 500–900°C , 2000 .

[3]  R. C. Newton,et al.  Experimental determination of CO2-H2O activity-composition relations at 600–1000 °C and 6–14 kbar by reversed decarbonation and dehydration reactions , 1999 .

[4]  R. C. Newton,et al.  Hypersaline fluids in Precambrian deep-crustal metamorphism , 1998 .

[5]  P. Philippot,et al.  Salt-rich aqueous fluids formed during eclogitization of metabasites in the Alpine continental crust (Austroalpine Mt. Emilius unit, Italian western Alps) , 1998 .

[6]  L. Franz,et al.  High‐Grade K‐Feldspar Veining in Granulites From the Ivrea‐Verbano Zone, Northern Italy: Fluid Flow in the Lower Crust and Implications For Granulite Facies Genesis , 1998, The Journal of Geology.

[7]  R. C. Newton,et al.  Reversed determination of the reaction: Phlogopite + quartz = enstatite + potassium feldspar + H2O in the ranges 750–875 °C and 2–12 kbar at low H2O activity with concentrated KCl solutions , 1998 .

[8]  V. Schenk,et al.  Fluid inclusions in high-pressure granulites of the Pan-African belt in Tanzania (Uluguru Mts): a record of prograde to retrograde fluid evolution , 1998 .

[9]  G. Markl,et al.  Composition of fluids in the lower crust inferred from metamorphic salt in lower crustal rocks , 1998, Nature.

[10]  D. Harlov,et al.  Oxide and sulphide minerals in highly oxidized, Rb‐depleted, Archaean granulites of the Shevaroy Hills Massif, South India: Oxidation states and the role of metamorphic fluids , 1997 .

[11]  R. C. Newton,et al.  H2O activity in concentrated NaCl solutions at high pressures and temperatures measured by the brucite-periclase equilibrium , 1996 .

[12]  K. Shmulovich,et al.  Melting of albite and dehydration of brucite in H2O–NaCl fluids to 9 kbars and 700–900°C: implications for partial melting and water activities during high pressure metamorphism , 1996 .

[13]  B. Goffé,et al.  Evolution of synmetamorphic veins and their wallrocks through a Western Alps transect : no evidence for large-scale fluid flow. Stable isotope, major- and trace-element systematics , 1996 .

[14]  G. Albino Sodium metasomatism along the Melones Fault Zone, Sierra Nevada Foothills, California, USA , 1995 .

[15]  Patrick J. Williams,et al.  Giant metasomatic system formed during exhumation of mid‐crustal Proterozoic rocks in the vicinity of the Cloncurry Fault, northwest Queensland , 1995 .

[16]  R. Stern,et al.  Regional Carbonate Alteration of the Crust by Mantle-Derived Magmatic Fluids, Tamil Nadu, South India , 1994, The Journal of Geology.

[17]  N. Oliver,et al.  The stable isotope signature of kilometre‐scale fracturedominated metamorphic fluid pathways, Mary Kathleen, Australia , 1993 .

[18]  M. Magaritz,et al.  Hydrothermal dolomite marbles associated with charnockitic magmatism in the Proterozoic Bamble Shear Belt, south Norway , 1993 .

[19]  A. K. V. Groos,et al.  Differential thermal analysis of the liquidus relations in the system NaCl-H2O to 6 kbar , 1991 .

[20]  P. Philippot,et al.  Trace-element-rich brines in eclogitic veins: implications for fluid composition and transport during subduction , 1991 .

[21]  I. Carmichael The redox states of basic and silicic magmas: a reflection of their source regions? , 1991 .

[22]  J. Gittins,et al.  Composition of the fluid phase accompanying carbonatite magma; a critical examination , 1990 .

[23]  R. Stern,et al.  Origin of late precambrian intrusive carbonates, eastern desert of Egypt and Sudan: C, O and Sr isotopic evidence , 1990 .

[24]  M. Barton,et al.  Fluid flow and metasomatism in a subduction zone hydrothermal system: Catalina Schist terrane, California , 1989 .

[25]  J. Fein,et al.  Calcite solubility and speciation in supercritical NaCl-HCl aqueous fluids , 1989 .

[26]  B. Chadwick,et al.  Facies distributions and structure of a Dharwar volcanosedimentary basin: evidence for late Archaean transpression in southern India? , 1989, Journal of the Geological Society.

[27]  A. Woolley,et al.  Fenitization at the Alnö carbonatite complex, Sweden; distribution, mineralogy and genesis , 1988 .

[28]  A. V. Lapin,et al.  ROCK-ASSOCIATION AND MORPHOLOGICAL TYPES OF CARBONATITE AND THEIR GEOTECTONIC ENVIRONMENTS , 1988 .

[29]  D. Craw,et al.  Structural geology and vein mineralisation in the Callery River headwaters, Southern Alps, New Zealand , 1987 .

[30]  J. Fein,et al.  Calcite solubility in supercritical CO2H2O fluids , 1987 .

[31]  A. V. Lapin,et al.  CARBONATITES OF THE TATAR DEEP-SEATED FAULT ZONE, SIBERIA , 1987 .

[32]  M. Crawford,et al.  Metamorphic Fluids: The Evidence from Fluid Inclusions , 1986 .

[33]  J. Touret Fluid Regime in Southern Norway: The Record of Fluid Inclusions , 1985 .

[34]  D. E. Ellis Stability and phase equilibria of chloride and carbonate bearing scapolites at 750°C and 4000 bar , 1978 .

[35]  A. J. Ellis The solubility of calcite in sodium chloride solutions at high temperatures , 1963 .

[36]  R. Bradley Thermodynamic calculations on phase equilibria involving fused salts; part I, General theory and application to equilibria involving calcium carbonate at high pressure , 1962 .

[37]  O. F. Tuttle,et al.  The System CaO–CO2–H2O and the Origin of Carbonatites , 1960 .

[38]  S. Clark Effect of Pressure on the Melting Points of Eight Alkali Halides , 1959 .

[39]  A. J. Ellis The solubility of calcite in carbon dioxide solutions , 1959 .

[40]  G. Baker,et al.  Scapolitization in the Cloncurry district of north-western Queensland , 1953 .

[41]  P. Niggli Untersuchungen an Karbonat‐ und ‐Chloridschmelzen , 1919 .