Experimental Investigation on the Transport of Sulfide Driven by Melt‐Rock Reaction in Partially Molten Peridotite

Extraction of sulfides from the partially molten mantle is vital to elucidate the cycling of metal and sulfur elements between different geochemical circles but has not been investigated systematically. Using laboratory experiments and theoretical calculations, this study documents systematical variations in lithologies and compositions of silicate minerals and melts, which are approximately consistent with the results of the thermodynamically‐constrained model. During a melt‐peridotite reaction, the dissolution of olivine and precipitation of new orthopyroxene generate an orthopyroxene‐rich layer between the melt source and peridotite. With increasing reaction degree, more melt is infiltrated into and reacts with upper peridotite, which potentially enhances the concomitant upward transport of dense sulfide droplets. Theoretical analyses suggest an energetically focused melt flow with a high velocity (∼170.9 μm/hr) around sulfide droplets through the pore throat. In this energic melt flow, we, for the first time, observed the mechanical coalescence of sulfide droplets, and the associated drag force was likely driving upward entrainment of fine μm‐scale sulfide. For coarse sulfide droplets whose sizes are larger than the pore throat in the peridotite, their entrainment through narrow constrictions in crystal framework seems to be physically possible only when high‐degree melt‐peridotite reaction drives high porosity of peridotite and channelized melt flows with extremely high velocity. Hence, the melt‐rock reaction could drive and enhance upward entrainment of μm‐ to mm‐scale sulfide in the partially molten mantle, potentially contributing to the fertilization of the sub‐continental lithospheric mantle and the endowment of metal‐bearing sulfide for the formation of magmatic sulfide deposits.

[1]  T. Kusky,et al.  Lithosphere tearing and foundering during continental subduction: Insights from Oligocene−Miocene magmatism in southern Tibet , 2023, Geological Society of America Bulletin.

[2]  L. Reisberg,et al.  Thermodynamic modeling of melt addition to peridotite: Implications for the refertilization of the non-cratonic continental mantle lithosphere , 2022, Chemical Geology.

[3]  C. Heinrich,et al.  Physical transport of magmatic sulfides promotes copper enrichment in hydrothermal ore fluids , 2022, Geology.

[4]  B. Godel,et al.  The critical role of magma degassing in sulphide melt mobility and metal enrichment , 2022, Nature Communications.

[5]  C. Xue,et al.  Copper isotope evidence for a Cu-rich mantle source of the world-class Jinchuan magmatic Ni-Cu deposit , 2022, American Mineralogist.

[6]  Z. Yao,et al.  Partitioning behaviors of cobalt and manganese along diverse melting paths of peridotitic and MORB-like pyroxenitic mantle , 2022, Journal of Petrology.

[7]  David C. Jones,et al.  Physics of Melt Extraction from the Mantle: Speed and Style , 2022, Annual Review of Earth and Planetary Sciences.

[8]  M. Fiorentini,et al.  Mobilisation of deep crustal sulfide melts as a first order control on upper lithospheric metallogeny , 2022, Nature Communications.

[9]  J. Mungall,et al.  Kinetic controls on the sulfide mineralization of komatiite-associated Ni-Cu-(PGE) deposits , 2021, Geochimica et Cosmochimica Acta.

[10]  J. Mungall,et al.  The Rustenburg Layered Suite formed as a stack of mush with transient magma chambers , 2021, Nature Communications.

[11]  Xiaolin Xiong,et al.  Element loss to platinum capsules in high-temperature–pressure experiments , 2020 .

[12]  J. Mungall,et al.  Flotation mechanism of sulphide melt on vapour bubbles in partially molten magmatic systems , 2020 .

[13]  Zhenmin Jin,et al.  Reaction Infiltration Instabilities in Partially Molten Peridotite and Implications for Driving the Transport of Sulfide Liquid , 2020, Journal of Earth Science.

[14]  Yan Liang,et al.  An experimental study of peridotite dissolution in eclogite-derived melts: Implications for styles of melt-rock interaction in lithospheric mantle beneath the North China Craton , 2020 .

[15]  Xianghui Xiao,et al.  Transport of coexisting Ni-Cu sulfide liquid and silicate melt in partially molten peridotite , 2020 .

[16]  R. Dasgupta,et al.  Sulfur extraction via carbonated melts from sulfide-bearing mantle lithologies – Implications for deep sulfur cycle and mantle redox , 2020 .

[17]  K. Qin,et al.  A Preliminary Model for the Migration of Sulfide Droplets in a Magmatic Conduit and the Significance of Volatiles , 2019 .

[18]  John Frederick Rudge,et al.  Fast magma ascent, revised estimates from the deglaciation of Iceland , 2019, Earth and Planetary Science Letters.

[19]  M. Holness,et al.  Microstructural evolution of silicate immiscible liquids in ferrobasalts , 2019, Contributions to Mineralogy and Petrology.

[20]  R. Sparks,et al.  Chemical differentiation, cold storage and remobilization of magma in the Earth’s crust , 2018, Nature.

[21]  K. Qin,et al.  Tectonic controls on Ni and Cu contents of primary mantle-derived magmas for the formation of magmatic sulfide deposits , 2018, American Mineralogist.

[22]  J. Koepke,et al.  Sulfide enrichment at an oceanic crust-mantle transition zone: Kane Megamullion (23°N, MAR) , 2018, Geochimica et Cosmochimica Acta.

[23]  K. Qin,et al.  Kinetic processes for plastic deformation of olivine in the Poyi ultramafic intrusion, NW China: Insights from the textural analysis of a ~ 1700 m fully cored succession , 2017 .

[24]  D. Kohlstedt,et al.  Reaction Infiltration Instabilities in Mantle Rocks: an Experimental Investigation , 2017 .

[25]  B. Wood,et al.  The S content of silicate melts at sulfide saturation: New experiments and a model incorporating the effects of sulfide composition , 2017 .

[26]  R. Dasgupta,et al.  The fate of sulfide during decompression melting of peridotite - implications for sulfur inventory of the MORB-source depleted upper mantle , 2017 .

[27]  S. Llana-Fúnez,et al.  An extension of the Saltykov method to quantify 3D grain size distributions in mylonites , 2016 .

[28]  T. Grove,et al.  Experiments on melt–rock reaction in the shallow mantle wedge , 2016, Contributions to Mineralogy and Petrology.

[29]  Wenliang Xu,et al.  Formation of orthopyroxenite by reaction between peridotite and hydrous basaltic melt: an experimental study , 2016, Contributions to Mineralogy and Petrology.

[30]  S. Barnes,et al.  Dynamics of Magmatic Sulphide Droplets during Transport in Silicate Melts and Implications for Magmatic Sulphide Ore Formation , 2015 .

[31]  D. Kohlstedt,et al.  Reaction infiltration instabilities in experiments on partially molten mantle rocks , 2015 .

[32]  F. Gaillard,et al.  Transport of metals and sulphur in magmas by flotation of sulphide melt on vapour bubbles , 2015 .

[33]  Youxue Zhang Toward a quantitative model for the formation of gravitational magmatic sulfide deposits , 2015 .

[34]  P. Scarlato,et al.  The effect of CO2 and H2O on Etna and Fondo Riccio (Phlegrean Fields) liquid viscosity, glass transition temperature and heat capacity , 2014 .

[35]  L. Montési,et al.  Experimental quantification of permeability of partially molten mantle rock , 2014 .

[36]  J. Brenan,et al.  Partitioning of platinum-group elements and Au between sulfide liquid and basalt and the origins of mantle-crust fractionation of the chalcophile elements , 2014 .

[37]  S. Barnes,et al.  Partition coefficients of chalcophile elements between sulfide and silicate melts and the early crystallization history of sulfide liquid : LA-ICP-MS analysis of MORB sulfide droplets , 2013 .

[38]  W. Griffin,et al.  Continental-root control on the genesis of magmatic ore deposits , 2013 .

[39]  Wenliang Xu,et al.  Effect of melt composition on basalt and peridotite interaction: laboratory dissolution experiments with applications to mineral compositional variations in mantle xenoliths from the North China Craton , 2013, Contributions to Mineralogy and Petrology.

[40]  Kevin W Eliceiri,et al.  NIH Image to ImageJ: 25 years of image analysis , 2012, Nature Methods.

[41]  R. Dasgupta,et al.  Reaction between MORB-eclogite derived melts and fertile peridotite and generation of ocean island basalts , 2012 .

[42]  A. Provost,et al.  Fate of Pyroxenite-derived Melts in the Peridotitic Mantle: Thermodynamic and Experimental Constraints , 2012 .

[43]  L. Reisberg,et al.  Volatile-rich metasomatism in montferrier xenoliths (Southern France) : implications for the abundances of chalcophile and highly siderophile elements in the subcontinental mantle , 2011 .

[44]  Francesco De Carlo,et al.  Microtomography of Partially Molten Rocks: Three-Dimensional Melt Distribution in Mantle Peridotite , 2011, Science.

[45]  D. Groves,et al.  Temporal and spatial controls on the formation of magmatic PGE and Ni–Cu deposits , 2011 .

[46]  T. Sisson,et al.  Segregating gas from melt: an experimental study of the Ostwald ripening of vapor bubbles in magmas , 2011 .

[47]  Michael Denis Higgins Textural coarsening in igneous rocks , 2011 .

[48]  C. Mandeville,et al.  Spectroscopic analysis (FTIR, Raman) of water in mafic and intermediate glasses and glass inclusions , 2010 .

[49]  T. Yoshino,et al.  Electrical conductivity of basaltic and carbonatite melt-bearing peridotites at high pressures: Implications for melt distribution and melt fraction in the upper mantle , 2010 .

[50]  A. Holzheid Separation of sulfide melt droplets in sulfur saturated silicate liquids , 2010 .

[51]  J. Lorand,et al.  Platinum-group element micronuggets and refertilization process in Lherz orogenic peridotite (northeastern Pyrenees, France) , 2010 .

[52]  N. Bagdassarov,et al.  Permeability of asthenospheric mantle and melt extraction rates at mid-ocean ridges , 2009, Nature.

[53]  N. Bagdassarov,et al.  Centrifuge assisted percolation of Fe–S melts in partially molten peridotite: Time constraints for planetary core formation , 2009 .

[54]  H. Chung,et al.  Physical constraints on the migration of immiscible fluids through partially molten silicates, with special reference to magmatic sulfide ores , 2009 .

[55]  W. Griffin,et al.  Sulfides in mantle peridotites from Penghu Islands, Taiwan : melt percolation, PGE fractionation, and the lithospheric evolution of the South China block , 2009 .

[56]  K. Kunze,et al.  Matrix rheology effects on reaction rim growth I: evidence from orthopyroxene rim growth experiments , 2009 .

[57]  T. Grove,et al.  Oxygen fugacity, temperature reproducibility, and H2O contents of nominally anhydrous piston-cylinder experiments using graphite capsules , 2008 .

[58]  D. Dingwell,et al.  Viscosity of magmatic liquids: A model , 2008 .

[59]  Lori E. Greene,et al.  Thermochemistry of sulfide liquids IV: density measurements and the thermodynamics of O–S–Fe–Ni–Cu liquids at low to moderate pressures , 2008 .

[60]  P. C. Hess,et al.  An experimental study of the grain-scale processes of peridotite melting: implications for major and trace element distribution during equilibrium and disequilibrium melting , 2008 .

[61]  Yanan Liu,et al.  Sulfur concentration at sulfide saturation (SCSS) in magmatic silicate melts , 2007 .

[62]  V. Laurenz,et al.  Fractionation of the noble metals by physical processes , 2006 .

[63]  Yan Liang,et al.  An experimental study of the kinetics of lherzolite reactive dissolution with applications to melt channel formation , 2005 .

[64]  Matthew C. Smith,et al.  Minimum speed limit for ocean ridge magmatism from 210Pb–226Ra–230Th disequilibria , 2005, Nature.

[65]  E. Watson,et al.  Growth kinetics of FeS melt in partially molten peridotite: An analog for core-forming processes , 2005 .

[66]  Paul D. Asimow,et al.  Adiabat_1ph: A new public front‐end to the MELTS, pMELTS, and pHMELTS models , 2005 .

[67]  Y. Niu Bulk-rock Major and Trace Element Compositions of Abyssal Peridotites: Implications for Mantle Melting, Melt Extraction and Post-melting Processes Beneath Mid-Ocean Ridges , 2004 .

[68]  Conny Bockrath,et al.  Fractionation of the Platinum-Group Elements During Mantle Melting , 2004, Science.

[69]  T. Yoshino,et al.  Connectivity of molten Fe alloy in peridotite based on in situ electrical conductivity measurements: implications for core formation in terrestrial planets , 2004 .

[70]  P. Scarlato,et al.  Sulfur diffusion in basaltic melts , 2004 .

[71]  Yan Liang,et al.  An experimental and numerical study of the kinetics of harzburgite reactive dissolution with applications to dunite dike formation , 2003 .

[72]  Christophe L. Martin,et al.  Pore size distributions calculated from 3-D images of DEM-simulated powder compacts , 2003 .

[73]  J. Lorand,et al.  Sulfide petrology and highly siderophile element geochemistry of abyssal peridotites: a coupled study of samples from the Kane Fracture Zone (45°W 23°20N, MARK area, Atlantic Ocean) , 2003 .

[74]  T. Yoshino,et al.  Core formation in planetesimals triggered by permeable flow , 2003, Nature.

[75]  J. Harris,et al.  Mass-Independent Sulfur of Inclusions in Diamond and Sulfur Recycling on Early Earth , 2002, Science.

[76]  W. Bai,et al.  Influence of melt on the creep behavior of olivine–basalt aggregates under hydrous conditions , 2002 .

[77]  Mark S. Ghiorso,et al.  The pMELTS: A revision of MELTS for improved calculation of phase relations and major element partitioning related to partial melting of the mantle to 3 GPa , 2002 .

[78]  A. Holzheid,et al.  Sulfur saturation limits in silicate melts and their implications for core formation scenarios for terrestrial planets , 2002 .

[79]  U. Faul Melt retention and segregation beneath mid-ocean ridges , 2001, Nature.

[80]  N. Arndt,et al.  Analog experimental insights into the formation of magmatic sulfide deposits , 2001 .

[81]  Marc Spiegelman,et al.  Causes and consequences of flow organization during melt transport: The reaction infiltration instability in compactible media , 2001 .

[82]  M. Schmitz,et al.  Textural equilibria of iron sulfide liquids in partly molten silicate aggregates and their relevance to core formation scenarios , 2000 .

[83]  D. McKenzie Constraints on melt generation and transport from U-series activity ratios , 2000 .

[84]  Yan Liang Diffusive dissolution in ternary systems: analysis with applications to quartz and quartzite dissolution in molten silicates , 1999 .

[85]  J. Mavrogenes,et al.  THE RELATIVE EFFECTS OF PRESSURE, TEMPERATURE AND OXYGEN FUGACITY ON THE SOLUBILITY OF SULFIDE IN MAFIC MAGMAS , 1999 .

[86]  Michael Denis Higgins Origin of Anorthosite by Textural Coarsening: Quantitative Measurements of a Natural Sequence of Textural Development , 1998 .

[87]  Donald B. Dingwell,et al.  Volcanic Dilemma--Flow or Blow? , 1996, Science.

[88]  John Whitehead,et al.  Channeling instability of upwelling melt in the mantle , 1995 .

[89]  P. Kelemen,et al.  Extraction of mid-ocean-ridge basalt from the upwelling mantle by focused flow of melt in dunite channels , 1995, Nature.

[90]  Mark S. Ghiorso,et al.  Chemical mass transfer in magmatic processes IV. A revised and internally consistent thermodynamic model for the interpolation and extrapolation of liquid-solid equilibria in magmatic systems at elevated temperatures and pressures , 1995 .

[91]  R. Bauman,et al.  Interpretation of Bernoulli’s equation , 1994 .

[92]  D. Kohlstedt,et al.  The transition from porous to channelized flow due to melt/rock reaction during melt migration , 1994 .

[93]  D. McKenzie Some remarks on the movement of small melt fractions in the mantle , 1989 .

[94]  Youxue Zhang,et al.  Diffusive crystal dissolution , 1989 .

[95]  Nikolaus von Bargen,et al.  Permeabilities, interfacial areas and curvatures of partially molten systems: Results of numerical computations of equilibrium microstructures , 1986 .

[96]  D. McKenzie,et al.  The Generation and Compaction of Partially Molten Rock , 1984 .

[97]  S. Karato Grain-size distribution and rheology of the upper mantle , 1984 .

[98]  N. Carter,et al.  Rheology of the upper mantle: Inferences from peridotite xenoliths , 1980 .

[99]  Y. Fung,et al.  Stokes flow around a circular cylindrical post confined between two parallel plates , 1969, Journal of Fluid Mechanics.

[100]  Carl Wagner,et al.  Theorie der Alterung von Niederschlägen durch Umlösen (Ostwald‐Reifung) , 1961, Zeitschrift für Elektrochemie, Berichte der Bunsengesellschaft für physikalische Chemie.

[101]  I. Lifshitz,et al.  The kinetics of precipitation from supersaturated solid solutions , 1961 .

[102]  Cin-Ty A. Lee,et al.  How to make porphyry copper deposits , 2020 .

[103]  A. Woodland,et al.  Thermodynamic Modelling of Mantle–Melt Interaction Evidenced by Veined Wehrlite Xenoliths from the Rockeskyllerkopf Volcanic Complex, West Eifel Volcanic Field, Germany , 2018 .

[104]  J. Lorand,et al.  Chalcophile and Siderophile Elements in Mantle Rocks: Trace Elements Controlled By Trace Minerals , 2016 .

[105]  Youxue Zhang,et al.  Diffusion Data in Silicate Melts , 2010 .

[106]  P. Kelemen,et al.  Trapped Melt in the Josephine Peridotite: Implications for Permeability and Melt Extraction in the Upper Mantle , 2010 .

[107]  W. Sun,et al.  Kinetics for coarsening co-controlled by diffusion and a reversible interface reaction , 2007 .

[108]  D. Scott,et al.  Grain growth in partially molten olivine aggregates , 2006 .

[109]  E. Christiansen,et al.  Contributions to mineralogy and petrology , 2006 .

[110]  J. Mungall Empirical models relating viscosity and tracer diffusion in magmatic silicate melts , 2002 .

[111]  D. Hoff,et al.  Reactive Infiltration Instabilities , 1986 .

[112]  S. A. Saltikov THE DETERMINATION OF THE SIZE DISTRIBUTION OF PARTICLES IN AN OPAQUE MATERIAL FROM A MEASUREMENT OF THE SIZE DISTRIBUTION OF THEIR SECTIONS , 1967 .