Mineralogical constraints on the formation of cumulates in layered intrusions in the Pan-Xi region, Sichuan Province, China

doi:10.13745/j.esf.sf.2020.5.33

Abstract

Abstract:

It is very important for understanding the igneous processes to discover that several crystal populations can be found in an igneous sample. The discovery makes genetic mineralogy again key to revealing the history of a magmatic system, however, this importance is not reflected in the literature. A typical example is the debate on the origin of cumulates in so-called mafic layered intrusions that wether the cumulated minerals are antecrysts or liquidus of the parent magma. In this contribution, we attempt to clarify the origin of cumulate formation in mafic layered intrusions in the Pan-Xi region, Sichuan Province, and to emphasize the importance of genetic mineralogy. Microscopic observations suggest that clinopyroxene cumulate is rich in Fe-Ti oxide exsolution lamellaes (lamellae-bearing pyroxene), indicating the magmatic condition of crystallizing lamellae-bearing pyroxene is obviously different from crystallizing clinopyroxene (lamellae-free pyroxene), which is co-crystallized with plagioclase. The olivine grains included in lamellae-free pyroxene and plagioclase are neaer-rounded, which suggests thermodynamic disequilibrium between olivine and melt. The Fe-Mg partitioning relation between olivine and melt reveals that liquidus olivine Fo value inferred from the parental magma is much lower than the upper limit of the composition range (Fo₆₁-Fo₈₁) of olivine in cumulate. In other words, the observed olivine grains, partly at least, are not of the liquidus phase of the host intrusion. Correlations between Mg^#[Mg/(Mg+Fe)] and minor elements (especially Ni) also suggest multiple olivine crystal populations formed under different thermodynamic conditions. Crystal settling analysis indicates that crystals precipitating from the host magma may not experience rapid gradational settling and cumulate. All the evidences show that the cumulate-forming mineral crystals are mainly arrived from different chambers at depths of the magmatic system, and they are of antecryst and transferred to the terminal magma chamber. Consequently, the cumulated minerals have larger initial grain radius, which is helpful for their rapid settling to the bottom of the intrusion at an earlier stage to form cumulate.

Key words: cumulate, olivine, antecryst, genetic mineralogy, Pan-Xi region

CLC Number:

P588.1
P571

LUO Zhaohua. Mineralogical constraints on the formation of cumulates in layered intrusions in the Pan-Xi region, Sichuan Province, China[J]. Earth Science Frontiers, 2020, 27(5): 61-69.

Figures/Tables 3

References 41

[1]	BOWEN N L. The evolution of igneous rocks[M]. Princeton: Princeton University Press, 1928.
[2]	GHIORSO M S, HIRSCHMANN M M, REINERS P W, 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[J]. Geochemistry, Geophysics, Geosystems, 2002, 3(5):1-35.
[3]	ARISKIN A A. Phase equilibria modeling in igneous petrology: use of COMAGMAT model for simulating fractionation of ferro-basaltic magmas and the genesis of high-alumina basalt[J]. Journal of Volcanology and Geothermal Research, 1999, 90:115-162.
[4]	JERRAM D A, MARTIN V M. Understanding crystal populations and their significance through the magma plumbing system[M]// ANNEN C, ZELLMER G F. Dynamics of crustal magma transfer, storage and differentiation. London: Geological Society, Special Publications, 2008, 304:133-148.
[5]	罗照华, 杨宗锋, 代耕, 等. 火成岩的晶体群与成因矿物学展望[J]. 中国地质, 2013, 40(1):176-181.
[6]	CHARLIER B L A, WILSON C J N, LOWENSTERN J B, et al. Magma generation at a large, hyperactive silicic volcano (Taupo, New Zealand) revealed by U-Th and U-Pb systematics in zircons[J]. Journal of Petrology, 2005, 46(1):3-32.
[7]	SAKYI P A, TANAKA R, KOBAYASHI K, et al. Inherited Pb isotopic records in olivine antecryst-hosted melt inclusions from Hawaiian lavas[J]. Geochimica et Cosmochimica Acta, 2012, 95:169-195. DOI URL
[8]	UBIDE T, GALÉ C, LARREA P, et al. Antecrysts and their effect on rock compositions: the Cretaceous lamprophyre suite in the Catalonian Coastal Ranges (NE Spain)[J]. Lithos, 2014, 206/207:214-233.
[9]	杨宗锋, 罗照华, 卢欣祥. 定量化火成岩结构分析与岩浆固结的动力学过程[J]. 地学前缘, 2010, 17(1):246-266.
[10]	VINET N, HIGGINS M D. What can crystal size distributions and olivine compositions tell us about magma solidification processes inside Kilauea Iki lava lake, Hawaii?[J]. Journal of Volcanology and Geothermal Research, 2011, 208:136-162. DOI URL
[11]	ZHOU M F, ROBINSON P T, LESHER C M, et al. Geochemistry, petrogenesis and metallogenesis of the Panzhihua gabbroic layered intrusion and associated Fe-Ti-V oxide deposits, Sichuan Province, SW China[J]. Journal of Petrology, 2005, 46:2253-2280.
[12]	PANG K N, LI C S, ZHOU M F, et al. Mineral compositional constraints on petrogenesis and oxide ore genesis of the late Permian Panzhihua layered gabbroic intrusion, SW China[J]. Lithos, 2009, 110:199-214.
[13]	BAI Z J, ZHONG H, NALDRETT A J, et al. Whole-rock and mineral composition constraints on the genesis of the giant Hongge Fe-Ti-V Oxide Deposit in the Emeishan Large Igneous Province, Southwest China[J]. Economic Geology, 2012, 107:507-524.
[14]	DONG H, XING C M, WANG C Y. Textures and mineral compositions of the Xinjie layered intrusion, SW China: implications for the origin of magnetite and fractionation process of Fe-Ti-rich basaltic magmas[J]. Geoscience Frontiers, 2013, 4:503-515. DOI URL
[15]	LUAN Y, SONG X Y, CHEN L M, et al. Key factors controlling the accumulation of the Fe-Ti oxides in the Hongge layered intrusion in the Emeishan Large Igneous Province, SW China[J]. Ore Geology Reviews, 2014, 57:518-538. DOI URL
[16]	张帆. 四川省盐源县矿山梁子苦橄质岩床研究及其与铁矿成矿作用关系[D]. 北京: 中国地质大学(北京), 2014.
[17]	WAGER L R, BROWN G M, WADSWORTH W J. Types of igneous cumulates[J]. Journal of Petrology, 1960, 1:73-85. DOI URL
[18]	HUNTER R H. Texture development in cumulate rocks[M]// CAWTHOM R G. Layered intrusions. Amsterdam: Elsevier, 1996: 77-101.
[19]	MARSH B D. Solidification fronts and magmatic evolution[J]. Mineralogical Magazine, 1996, 60:5-40. DOI URL
[20]	HOLNESS M B, NIELSEN T F D, TEGNER C. Textural maturity of cumulates: a record of chamber filling, liquidus assemblage, cooling rate and large-scale convection in mafic layered intrusions[J]. Journal of Petrology, 2007, 48:141-157. DOI URL
[21]	NAMUR O, ABILY B, BOUDREAU A E, et al. Igneous layering in basaltic magma chambers[M]// CHARLIER B, NAMUR O, LATYPOV R, et al. Layered intrusions. Berlin: Springer, 2015: 75-152.
[22]	罗照华. 为什么火成岩地球化学需要地质学、岩石学和矿物学证据约束?[J]. 地球科学与环境学报, 2017, 39(3):326-343.
[23]	四川省地质矿产局. 四川省区域地质志[M]. 北京: 地质出版社, 1991.
[24]	ROEDER P L, EMSLIE R F. Olivine-liquid equilibrium[J]. Contributions to Mineralogy and Petrology, 1970, 29:275-289.
[25]	LEE C T A, LUFFI P, PLANK T, et al. Constraints on the depths and temperatures of basaltic magma generation on Earth and other terrestrial planets using new thermobarometers for mafic magmas[J]. Earth and Planetary Science Letters, 2009, 279:20-33.
[26]	FILIBERTO J, DASGUPTA R. Fe²+-Mg partitioning between olivine and basaltic melts: applications to genesis of olivine-phyric shergottites and conditions of melting in the Martian interior[J]. Earth and Planetary Science Letters, 2011, 304:527-537.
[27]	DUKE J M. Computer simulation of the fractionation of olivine and sulfide from mafic and ultramafic magmas[J]. Canadian Mineralogist, 1979, 17:507-514.
[28]	DAVIDSON P M, MUKHOPADHYAY D K. Ca- Fe- Mg olivines: phase relations and a solution model[J]. Contributions to Mineralogy and Petrology, 1984, 86:256-263. DOI URL
[29]	JUREWICZ A J G, WATSON E B. Cations in olivine, Part 1: calcium partitioning and calcium-magnesium distribution between olivines and coexisting melts, with petrologic applications[J]. Contributions to Mineralogy and Petrology, 1988, 99:176-185. DOI URL
[30]	JUREWICZ A J G, WATSON E B. Cations in olivine, Part 2: diffusion in olivine xenocrysts, with applications to petrology and mineral physics[J]. Contributions to Mineralogy and Petrology, 1988, 99:186-201. DOI URL
[31]	AGEE C B, WALKER D. Aluminum partitioning between olivine and ultrabasic silicate liquid to 6 GPa[J]. Contributions to Mineralogy and Petrology, 1990, 105:243-254. DOI URL
[32]	LI C S, NALDRETT A J, RIPLEY E M. Controls on the Fo and Ni contents of olivine in sulfide-bearing mafic/ultramafic intrusions: principles, modeling, and examples from Voisey’s Bay[J]. Earth Science Frontiers, 2007, 14(5):177-185. DOI URL
[33]	SPANDLER C, O’NEILL H S C. Diffusion and partition coefficients of minor and trace elements in San Carlos olivine at 1 300℃ with some geochemical implications[J]. Contributions to Mineralogy and Petrology, 2009, 159:791-818. DOI: 10. 1007/s00410-009-0456-8. DOI URL
[34]	NWE Y Y. Electron-probe studies of the earlier pyroxenes and olivines from the Skaergaard intrusion, East Greenland[J]. Contributions to Mineralogy and Petrology, 1976, 55:105-126.
[35]	SIMKIN T, SMITH J V. Minor-element distribution in olivine[J]. The Journal of Geology, 1970, 78(3):304-325. DOI URL
[36]	KAMENETSKY V S, ELBURG M, ARCULUS R, et al. Magmatic origin of low-Ca olivine in subduction-related magmas co-existence of contrasting magmas[J]. Chemical Geology, 2006, 233:346-357. DOI URL
[37]	CHENG L L, ZENG L, REN Z Y, et al. Timescale of emplacement of the Panzhihua gabbroic layered intrusion recorded in giant plagioclase at Sichuan Province, SW China[J]. Lithos, 2014, 204:203-219. DOI URL
[38]	SCHWINDINGER K R. Particle dynamics and aggregation of crystals in a magma chamber with application to Kilauea Iki olivines[J]. Journal of Volcanology and Geothermal Research, 1999, 88:209-238.
[39]	SCHMIDT M W, FORIEN M, SOLFERINO G, et al. Settling and compaction of olivine in basaltic magmas: an experimental study on the time scales of cumulate formation[J]. Contributions to Mineralogy and Petrology, 2012, 164:959-976.
[40]	BURGISSER A, BERGANTZ G W, BREIDENTHAL R E. Addressing complexity in laboratory experiments: the scaling of dilute multiphase flows in magmatic systems[J]. Journal of Volcanology and Geothermal Research, 2005, 141:245-265.
[41]	MARSH B D. On some fundamentals of igneous petrology[J]. Contributions to Mineralogy and Petrology, 2013, 166:665-690. DOI URL