Dunite xenoliths and olivine xenocrysts in gabbro from Taihang Mountains: Characteristics of Mesozoic lithospheric mantle in Central China

Wenliang Xu, Chunguang Wang, Debin Yang, Feng Wang, Fuping Pei

Journal of Earth Science ›› 2010, Vol. 21 ›› Issue (5) : 692-710.

Journal of Earth Science ›› 2010, Vol. 21 ›› Issue (5) : 692-710. DOI: 10.1007/s12583-010-0121-1
Article

Dunite xenoliths and olivine xenocrysts in gabbro from Taihang Mountains: Characteristics of Mesozoic lithospheric mantle in Central China

Author information +
History +

Abstract

This article reports the petrography and mineral chemistry of dunite xenoliths and olivine xenocrysts entrained by the Early Cretaceous Xi’anli (西安里) hornblende (Hb)-gabbros from the southern Taihang (太行) Mountains, with the aim of constraining the nature of the Mesozoic lithospheric mantle in Central China. Rounded dunite xenoliths are 1–3 cm3 in size and display porphyroclastic, tabular, and protogranular textures. Chromite with Cr#=60–89 is common in the xenoliths. Olivine xenocrysts of 4–6 mm in size are also found in the Hb-gabbros. Orthopyroxene reaction rims are commonly observed around olivine xenocrysts or between dunite xenoliths and host rocks. The porphyroclastic olivines within dunite xenoliths and olivine xenocrysts have kink bands and Mg#=83–94. The Mg# of olivine cores and rims are 89–94 (average, 90) and 83–86 (average, 84.4), respectively. The CaO contents of all olivines from the xenoliths and xenocrysts are less than 0.1 wt.%, suggesting a lithospheric mantle origin. The Ca content (214 ppm–818 ppm) and Ti content (15 ppm–137 ppm) in the xenoliths and xenocrysts are similar to those of olivines from the dunite xenoliths, but are much higher than those of olivines from harzburgite and lherzolite xenoliths in the Fushan (符山) intrusion. This finding implies that the xenoliths and xenocrysts may have originated from harzburgites or lherzolites that were intensively modified by silica-rich melts. This result, combined with high Mg# (92–94) of olivine cores from the dunite xenoliths and xenocrysts, indicates that these olivine xenocrysts and dunite xenoliths could represent the residue of ancient (Archean or Paleoproterozoic) lithospheric mantle and might have experienced the same intensive modification by silica-rich melts as the host magma, resulting in enrichment in MgO and SiO2.

Keywords

North China craton / Xi’anli / Hb-gabbro / dunite / xenocryst / lithospheric mantle

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾
Wenliang Xu, Chunguang Wang, Debin Yang, Feng Wang, Fuping Pei. Dunite xenoliths and olivine xenocrysts in gabbro from Taihang Mountains: Characteristics of Mesozoic lithospheric mantle in Central China. Journal of Earth Science, 2010, 21(5): 692‒710 https://doi.org/10.1007/s12583-010-0121-1

References

Publishing order | Descend order by publishing year | Descend order by cited within
Becker H., Shirey S. B., Carlson R. W.. Effects of Melt Percolation on the Re-Os Systematics of Peridotites from a Paleozoic Convergent Plate Margin. Earth Planet. Sci. Lett., 2001, 188(1–2): 107-121.
CrossRef Google scholar
Bernstein S., Kelemen P. B., Hanghoj K.. Consistent Olivine Mg# in Cratonic Mantle Reflects Archean Mantle Melting to the Exhaustion of Orthopyroxene. Geology, 2007, 35: 459-462.
CrossRef Google scholar
Boyd F. R.. Compositional Distinction between Oceanic and Cratonic Lithosphere. Earth Planet. Sci. Lett., 1989, 96(1–2): 15-26.
CrossRef Google scholar
Boynton W. V.. Henderson P.. Cosmochemistry of the Rare Earth Elements: Meteorite Studies. Rare Earth Element Geochemistry, 1984, New York: Elsevier Science Publishing Company Inc. 63 114
Carswell D. A.. Mantle Derived Lherzolite Nodules Associated with Kimberlite, Carbonatite and Basalt Magmatism: A Review. Lithos, 1980, 13(2): 121-138.
CrossRef Google scholar
Chen B., Jahn B. M., Arakawa Y., . Petrogenesis of the Mesozoic Intrusive Complexes from the Southern Taihang Orogen, North China Craton: Elemental and Sr-Nd-Pb Isotopic Constraints. Contrib. Mineral. Petrol., 2004, 148(4): 489-501.
CrossRef Google scholar
Dhuime B., Bosch D., Bodinier J. L., . Multistage Evolution of the Jijal Ultramafic-Mafic Complex (Kohistan, N Pakistan): Implications for Building the Roots of Island Arcs. Earth Planet. Sci. Lett., 2007, 261(1–2): 179-200.
CrossRef Google scholar
Dhuime B., Bosch D., Garrido C. J., . Geochemical Architecture of the Lower- to Middle-Crustal Section of a Paleo-island Arc (Kohistan Complex, Jijal-Kamila Area, Northern Pakistan): Implications for the Evolution of an Oceanic Subduction Zone. J. Petrol., 2009, 50(3): 531-569.
CrossRef Google scholar
E M. R., Zhao D. S.. Cenozoic Basalts and Deep-Seated Xenolith in Eastern China, 1987, Beijing: Science Press 490
Fan W. M., Guo F., Wang Y. J., . Late Mesozoic Volcanism in the Northern Huaiyang Tectono-magmatic Belt, Central China: Partial Melts from a Lithospheric Mantle with Subducted Continental Crust Relicts beneath the Dabie Orogen?. Chem. Geol., 2004, 209(1–2): 27-48.
CrossRef Google scholar
Fan W. M., Menzies M. A.. Destruction of Aged Lower Lithosphere and Accretion of Asthenospheric Mantle beneath Eastern China. Geotect. Metallogen., 1992, 16: 171-180.
Fan W. M., Zhang H. F., Baker J., . On and Off the North China Craton: Where is the Archaean Keel?. J. Petrol., 2000, 41(7): 933-950.
CrossRef Google scholar
Frey F. A., Prinz M. H.. Ultramafic Inclusions from San Carlos, Arizona, Petrologic and Geochemical Data Bearing on Their Petrogenesis. Earth Planet. Sci. Lett., 1978, 38(1): 129-176.
CrossRef Google scholar
Gao S., Liu X. M., Yuan H. L., . Determination of Forty-Two Major and Trace Elements in USGS and NIST SRM Glasses by LA-ICPMS. Geostand. Newsletter, 2002, 26(2): 181-196.
CrossRef Google scholar
Gao S., Rudnick R. L., Carlson R. W., . Re-Os Evidence for Replacement of Ancient Mantle Lithosphere beneath the North China Craton. Earth Planet. Sci. Lett., 2002, 198(3–4): 307-322.
CrossRef Google scholar
Gao S., Rudnick R. L., Xu W. L., . Recycling Deep Cratonic Lithosphere and Generation of Intraplate Magmatism. Earth Planet. Sci. Lett., 2008, 270(1–2): 41-53.
CrossRef Google scholar
Gao S., Rudnick R. L., Yuan H. L., . Recycling Lower Continental Crust in the North China Craton. Nature, 2004, 432(7019): 892-897.
CrossRef Google scholar
Garrido C. J., Bodinier J. L., Burg J. P., . Petrogenesis of Mafic Garnet Granulite in the Lower Crust of the Kohistan Paleo-arc Complex (Northern Pakistan): Implications for Intra-crustal Differentiation of Island Arcs and Generation of Continental Crust. J. Petrol., 2006, 47(10): 1873-1914.
CrossRef Google scholar
Garrido C. J., Bodinier J. L., Dhuime B., . Origin of the Island Arc Moho Transition Zone via Melt-Rock Reaction and Its Implications for Intracrustal Differentiation of Island Arcs: Evidence from the Jijal Complex (Kohistan Complex, Northern Pakistan). Geology, 2007, 35: 683-686.
CrossRef Google scholar
Griffin W. L., Zhang A. D., O’Reilly S. Y., . Flower M., Chung S. L., Lo C. H., . Phanerozoic Evolution of the Lithosphere beneath the Sino-Korean Craton. Mantle Dynamics and Plate Interactions in East Asia. Amer, 1998, Washington D.C.: Geodynamics, American Geophysical Union 107 126
Guo F., Fan W. M., Wang Y. J., . Geochemistry of Late Mesozoic Mafic Magmatism in West Shandong Province, Eastern China: Characterizing the Lost Lithospheric Mantle beneath the North China Block. Geochem. J., 2003, 37(1): 63-77.
Huang F. S., Xue S. Z.. The Discovery of the Mantle Derived Ultramafic Xenoliths in Handan-Xingtai Intrusive Complex and Their Mineralogical-Geochemical Characteristics. Acta Petrol. Sin., 1990, 4: 40-45.
Jan M. Q., Windley B. F.. Chromian Spinel Silicate Chemistry in Ultramafic Rocks of the Jijal Complex, Northwest Pakistan. J. Petrol., 1990, 31(3): 667-715.
Kelemen P. B.. Reaction between Ultramafic Rock and Fractionating Basaltic Magma: I. Phase Relations, the Origin of Calc-Alkaline Magma Series, and the Formation of Discordant Dunite. J. Petrol., 1990, 31(1): 51-98.
Kelemen P. B., Hart S. R., Bernstein S.. Silica Enrichment in the Continental Upper Mantle via Melt/Rock Reaction. Earth Planet. Sci. Lett., 1998, 164(1–2): 387-406.
CrossRef Google scholar
Kelemen P. B., Shimizu N., Salters V. J. M.. Extraction of Mid-Ocean-Ridge Basalt from the Upwelling Mantle by Focused Flow of Melt in Dunite Channels. Nature, 1995, 375(6534): 747-753.
CrossRef Google scholar
Köhler T. P., Brey G. P.. Calcium Exchange between Olivine and Clinopyroxene Calibrated as a Geothermobarometer for Natural Peridotites from 2 to 60 kb with Applications. Geochim. Cosmochim. Acta, 1990, 54: 2375-2388.
CrossRef Google scholar
Lee S. Y., Walker R. J.. Re-Os Isotope Systematics of Mantle Xenoliths from South Korea: Evidence for Complex Growth and Loss of Lithospheric Mantle beneath East Asia. Chem. Geol., 2006, 231(1–2): 90-101.
CrossRef Google scholar
Lu F. X., Wang Y., Chen M. H., . Geochemical Characteristics and Emplacement Ages of the Mengyin Kimberlites, Shandong Province, China. Int. Geol. Rev., 1998, 40(11): 998-1006.
CrossRef Google scholar
Lu F. X., Zheng J. P.. Chi J. S., Lu F. X.. Characteristics of Paleozoic Lithosphere and Deep Processes in the Noth China Platform. Characteristics of Kimberlites and Paleozoic Lithosphere in the North China Platform, 1996, Beijing: Science Press 215 274
Marchesi C., Garrido C. J., Godard M., . Petrogenesis of Highly Depleted Peridotites and Gabbroic Rocks from the Mayari-Baracoa Ophiolitic Belt (Eastern Cuba). Contrib. Mineral. Petrol., 2006, 151(6): 717-736.
CrossRef Google scholar
Marchesi C., Garrido C. J., Godard M., . Migration and Accumulation of Ultra-depleted Subduction-Related Melts in the Massif du Sud Ophiolite (New Caledonia). Chem. Geol., 2009, 266(3–4): 180-195.
Menzies M. A., Fan W. M., Zhang M.. Palaeozoic and Cenozoic Lithoprobes and the Loss of >120 km of Archaean Lithosphere, Sino-Korean Craton, China. Geol. Soc. Spec. Pub., 1993, 76: 71-81.
CrossRef Google scholar
Menzies M. A., Xu Y. G., . Flower J., Chung S. L., Lo C. H., . Geodynamics of the North China Craton. Mantle Dynamics and Plate Interactions in East Asia. Amer, 1998, Washington D.C.: Geodynamics, American Geophysical Union 155 165
Menzies M. A., Xu Y. G., Zhang H. F., . Integration of Geology, Geophysics and Geochemistry: A Key to Understanding the North China Craton. Lithos, 2007, 96(1–2): 1-21.
CrossRef Google scholar
Mercier J. C., Nicolas A.. Textures and Fabrics of Upper Mantle Peridotites as Illustrated by Xenoliths from Basalts. J. Petrol., 1975, 16(2): 454-487.
Morgan Z., Liang Y.. An Experimental and Numerical Study of the Kinetics of Harzburgite Reactive Dissolution with Applications to Dunite Dike Formation. Earth Planet. Sci. Lett., 2003, 214(1–2): 59-74.
CrossRef Google scholar
Morgan Z., Liang Y.. An Experimental Study of the Kinetics of Lherzolite Reactive Dissolution with Applications to Melt Channel Formation. Contrib. Mineral. Petrol., 2005, 150(4): 369-385.
CrossRef Google scholar
Pei F. P., Xu W. L., Wang Q. H., . Mesozoic Basalt and Mineral Chemistry of the Mantle-Derived Xenocrysts in Feixian, Western Shandong, China: Constraints on Nature of Mesozoic Lithospheric Mantle. Geological Journal of China Universities, 2004, 10(1): 88-97.
Pouchou J. L., Pichoir F.. A New Model for Quantitative X-Ray Microanalysis, Part 1: Application to the Analysis of Homogeneous Samples. Recherche Aerospatiale, 1984, 5(3): 167-192.
Quick J. E.. The Origin and Significance of Large, Tabular Dunite Bodies in the Trinity Peridotite, Northern California. Contrib. Mineral. Petrol., 1982, 78(4): 413-422.
CrossRef Google scholar
Roeder P. L., Emslie R. F.. Olivine-Liquid Equilibrium. Contrib. Mineral. Petrol., 1970, 29(4): 275-289.
CrossRef Google scholar
Rudnick R. L., Gao S., Ling W. L., . Petrology and Geochemistry of Spinel Peridotite Xenoliths from Hannuoba and Qixia, North China Craton. Lithos, 2004, 77(1–4): 609-637.
CrossRef Google scholar
Rudnick R. L., McDonough W. F., Orpin A.. Meyer H. O. A., Leonardos O.. Northern Tanzanian Peridotite Xenoliths: A Comparison with Kaapvaal Peridotites and Inferences on Metasomatic Interactions. Kimberlites, Related Rocks and Mantle Xenoliths. Proceedings Fifth Int. Kimb. Conf., 1994, Brasilia: CRPM 336 353
Shaw C. S. J., Dingwell D. B.. Experimental Peridotite-Melt Reaction at One Atmosphere: A Textural and Chemical Study. Contrib. Mineral. Petrol., 2008, 155(2): 199-214.
CrossRef Google scholar
Shaw C. S. J., Heidelbach F., Dingwell D. B.. The Origin of Reaction Textures in Mantle Peridotite Xenoliths from Sal Island, Cape Verde: The Case for Metasomatism by the Host Lava. Contrib. Mineral. Petrol., 2006, 151(6): 681-697.
CrossRef Google scholar
Thompson R. N., Gibson S. A.. Transient High Temperatures in Mantle Plume Heads Inferred from Magnesian Olivines in Phanerozoic Picrites. Nature, 2000, 407(6803): 502-506.
CrossRef Google scholar
Wang, C. G., Xu, W. L., Wang, F., et al., 2010. Petrogenesis of the Early Cretaceous Xi’anli Hb-Gabbros, Central China: Evidence from Zircon U-Pb Ages and Hf Isotope as well as Whole-Rock Geochemistry. Mineral. and Petrol., (Submitted) (in Chinese with English Abstract)
Wang Y. J., Fan W. M., Zhang H. F., . Early Cretaceous Gabbroic Rocks from the Taihang Mountains: Implications for a Paleosubduction-Related Lithospheric Mantle beneath the Central North China Craton. Lithos, 2006, 86(3–4): 281-302.
CrossRef Google scholar
Wilde S. A., Zhou X. H., Nemchin A. A., . Mesozoic Crust-Mantle Interaction beneath the North China Craton: A Consequence of the Dispersal of Gondwanaland and Accretion of Asia. Geology, 2003, 31: 817-820.
CrossRef Google scholar
Wu F. Y., Lin J. Q., Wilde S. A., . Nature and Significance of the Early Cretaceous Giant Igneous Event in Eastern China. Earth Planet. Sci. Lett., 2005, 233(1–2): 103-119.
CrossRef Google scholar
Wu F. Y., Walker R. J., Ren X. W., . Osmium Isotopic Constraints on the Age of Lithospheric Mantle beneath Northeastern China. Chem. Geol., 2003, 196(1–4): 107-129.
CrossRef Google scholar
Wu F. Y., Walker R. J., Yang Y. H., . The Chemical-Temporal Evolution of Lithospheric Mantle Underlying the North China Craton. Geochim. Cosmochim. Acta, 2006, 70(19): 5013-5034.
CrossRef Google scholar
Xu J. W., Zhu G.. Tectonic Models of the Tan-Lu Fault Zone, Eastern China. Inter. Geol. Rev., 1994, 36(8): 771-784.
CrossRef Google scholar
Xu W. L., Gao S., Wang Q. H., . Mesozoic Crustal Thickening of the Eastern North China Craton: Evidence from Eclogite Xenoliths and Petrologic Implications. Geology, 2006, 34: 721-724.
CrossRef Google scholar
Xu W. L., Hergt J. M., Gao S., . Interaction of Adakitic Melt-Peridotite: Implications for the High-Mg# Signature of Mesozoic Adakitic Rocks in the Eastern North China Craton. Earth Planet. Sci. Lett., 2008, 265(1–2): 123-137.
CrossRef Google scholar
Xu W. L., Lin J. Q.. The Discovery and Study of Mantle-Derived Dunite Inclusions in Hornblende-Diorite in Handan-Xingtai Area, Hebei, China. Acta Geol. Sin., 1991, 65(1): 33-41.
Xu W. L., Wang D. Y., Gao S., . Discovery of Dunite and Pyroxenite Xenoliths in Mesozoic Diorite at Jinling, Western Shandong and Its Significance. Chin. Sci. Bull., 2003, 48(8): 863-868.
Xu W. L., Yang D. B., Gao S., . Mesozoic Lithospheric Mantle of the Central North China Craton: Evidence from Peridotite Xenoliths. Geochim. Cosmochim. Acta, 2008, 72 Suppl.1 A1047
Xu W. L., Yang D. B., Gao S., . Geochemistry of Peridotite Xenoliths in Early Cretaceous High-Mg# Diorites from the Central Orogenic Block of the North China Craton: The Nature of Mesozoic Lithospheric Mantle and Constraints on Lithospheric Thinning. Chem. Geol., 2010, 270(1–4): 257-273.
CrossRef Google scholar
Xu W. L., Yuan C., Chi X. G., . Mesozoic Dioritic Rocks and Deep-Seated Inclusions in Central North China Platform, 1993, Beijing: Geological Publishing Press 164
Xu W. L., Zheng C. Q., Wang D. Y.. Discovery of Mantle- and Lower Crust-Derived Xenoliths in Mesozoic Trachybasalts from Western Liaoning, and Their Geological Implications. Geol. Rev., 1999, 45: 444-449.
Xu, X. S., O’Reilly, S. Y., Griffin, W. L., et al., 1998. The Nature of the Cenozoic Lithosphere at Nushan, Eastern China. In: Flower, M., Chung, S. L., Lo, C. H., et al., eds., Mantle Dynamics and Plate Interactions in East Asia. American Geophysical Union Geodynamics Series, Washington DC, 27: 167–196
Xu Y. G.. Thermo-tectonic Destruction of the Archaean Lithospheric, Keel beneath the Sino-Korean Craton in China: Evidence, Timing and Mechanism. Phys. Chem. Earth A, 2001, 26(9–10): 747-757.
CrossRef Google scholar
Xu Y. G., Huang X. L., Ma J. L., . Crust-Mantle Interaction during the Tectono-thermal Reactivation of the North China Craton: Constraints from SHRIMP Zircon U-Pb Chronology and Geochemistry of Mesozoic Plutons from Western Shandong. Contrib. Mineral. Petrol., 2004, 147(6): 750-767.
CrossRef Google scholar
Xu Y. G., Ma J. L., Frey F. A., . The Role of Lithosphere-Asthenosphere Interaction in the Genesis of Quaternary Alkali and Tholeiitic Basalts from Datong, Western North China Craton. Chem. Geol., 2005, 224(4): 247-271.
CrossRef Google scholar
Yan J., Chen J. F., Xie Z., . Mantle Xenoliths from Late Cretaceous Basalt in Eastern Shandong Province: New Constraint on the Time of Lithospheric Thinning in Eastern China. Chin. Sci. Bull., 2003, 48(14): 1570-1574.
Yang D. B., Xu W. L., Wang Q. H., . Chronology and Geochemistry of Mesozoic Granitoids in the Bengbu Area, Central China: Constraints on the Tectonic Evolution of the Eastern North China Craton. Lithos, 2010, 114(1–2): 200-216.
CrossRef Google scholar
Yang J. H., Wu F. Y., Wilde S. A., . Mesozoic Decratonization of the North China Block. Geology, 2008, 36: 467-470.
CrossRef Google scholar
Zhang H. F., Sun M., Zhou X. H., . Mesozoic Lithosphere Destruction beneath the North China Craton: Evidence from Major-, Trace Element and Sr-Nd-Pb Isotope Studies of Fangcheng Basalts. Contrib. Mineral. Petrol., 2002, 144(2): 241-253.
CrossRef Google scholar
Zhang J., Zhang H. F., Yin J. F., . Are the Peridotitic Xenoliths Entrained in Late Mesozoic Intermediate-Mafic Intrusive Complexes on the North China Craton: The Direct Samples of Lithospheric Mantle?. Acta Petrologica Sinica, 2005, 21(6): 1559-1568.
Zhao G. C., Cawood P. A., Wilde S. A., . Metamorphism of Basement Rocks in the Central Zone of the North China Craton: Implications for Paleoproterozoic Tectonic Evolution. Precamb. Res., 2000, 103(1–2): 55-88.
CrossRef Google scholar
Zhao G. C., Cawood P. A., Wilde S. A., . High-Pressure Granulites (Retrograded Eclogites) from the Hengshan Complex, North China Craton: Petrology and Tectonic Implications. J. Petrol., 2001, 42(6): 1141-1170.
CrossRef Google scholar
Zhao G. C., Cawood P., Lu L. Z.. Petrology and P-T History of the Wutai Amphibolites: Implications for Tectonic Evolution of the Wutai Complex, China. Precamb. Res., 1999, 93(2–3): 181-199.
CrossRef Google scholar
Zhao G. C., Wilde S. A., Cawood P. A., . Archean Blocks and Their Boundaries in the North China Craton: Lithological, Geochemical, Structural and P-T Path Constraints and Tectonic Evolution. Precamb. Res., 2001, 107(1–2): 45-73.
CrossRef Google scholar
Zheng J. P.. Mesozoic-Cenozoic Mantle Replacement and Lithospheric Thinning, 1999, Wuhan: China University of Geosciences Press 126
Zheng J. P., Griffin W. L., O’Reilly S. Y., . Mechanism and Timing of Lithospheric Modification and Replacement beneath the Eastern North China Craton: Peridotitic Xenoliths from the 100 Ma Fuxin Basalts and a Regional Synthesis. Geochim. Cosmochim. Acta, 2007, 71(21): 5203-5225.
CrossRef Google scholar
Zheng J. P., O’Reilly S. Y., Griffin W. L., . Relict of Refractory Mantle beneath the Eastern North China Block: Significance for Lithosphere Evolution. Lithos, 2001, 57(1): 43-66.
CrossRef Google scholar

Accesses

Citations

Detail
Sections
Recommended

/