Evolution of the melt source during protracted crustal anatexis: An example from the Bhutan Himalaya

The chemical compositions of magmatic zircon growth zones provide powerful insight into evolving magma compositions due to their ability to record both time and the local chemical environment. In situ U-Pb and Hf isotope analyses of zircon rims from Oligocene–Miocene leucogranites of the Bhutan Himalaya reveal, for the first time, an evolution in melt composition between 32 and 12 Ma. The data indicate a uniform melt source from 32 Ma to 17 Ma, and the progressive addition of an older source component to the melt from at least ca. 17 Ma. Age-corrected ɛHf ratios decrease from between −10 and −15 down to values as low as −23 by 12 Ma. Complementary whole-rock Nd isotope data corroborate the Hf data, with a progressive decrease in ɛNd(t) from ca. 18 to 12 Ma. Published zircon and whole-rock Nd data from different lithotectonic units in the Himalaya suggest a chemical distinction between the younger Greater Himalayan Series (GHS) and the older Lesser Himalayan Series (LHS). The time-dependent isotopic evolution shown in the leucogranites demonstrates a progressive increase in melt contribution from older lithologies, suggestive of increasing LHS involvement in Himalayan melting over time. The time-resolved data are consistent with LHS material being progressively accreted to the base of the GHS from ca. 17 Ma, facilitated by deformation along the Main Central thrust. From 17 Ma, decompression, which had triggered anatexis in the GHS since the Paleogene, enabled melting in older sources from the accreted LHS, now forming the lowermost hanging wall of the thrust.

[1]  N. Roberts,et al.  Deconvolving the pre-Himalayan Indian margin – Tales of crustal growth and destruction , 2019, Geoscience Frontiers.

[2]  Qiuping Liu,et al.  Diverse magma sources for the Himalayan leucogranites: Evidence from B-Sr-Nd isotopes , 2018, Lithos.

[3]  R. Parrish,et al.  The identification and significance of pure sediment-derived granites , 2017 .

[4]  P. Fiannacca,et al.  Timescales and mechanisms of batholith construction: Constraints from zircon oxygen isotopes and geochronology of the late Variscan Serre Batholith (Calabria, southern Italy) , 2017 .

[5]  Thomas N. Hopkinson Geochemical Insights into Crustal Melting in the Bhutan Himalaya , 2016 .

[6]  R. Parrish,et al.  The geology and tectonics of central Bhutan , 2015, Journal of the Geological Society.

[7]  R. Parrish,et al.  Using U‐Th‐Pb petrochronology to determine rates of ductile thrusting: Time windows into the Main Central Thrust, Sikkim Himalaya , 2015 .

[8]  Peter A. Cawood,et al.  Generation and preservation of continental crust in the Grenville Orogeny , 2015 .

[9]  G. Stevens,et al.  Small-scale Hf isotopic variability in the Peninsula pluton (South Africa): the processes that control inheritance of source 176Hf/177Hf diversity in S-type granites , 2014, Contributions to Mineralogy and Petrology.

[10]  Tao Yang,et al.  Hafnium isotopic heterogeneity in zircons from granitic rocks: Geochemical evaluation and modeling of "zircon effect" in crustal anatexis , 2014 .

[11]  S. Gupta,et al.  Tectonic interleaving along the Main Central Thrust, Sikkim Himalaya , 2014, Journal of the Geological Society.

[12]  T. Ahmad,et al.  Timescales of partial melting in the Himalayan middle crust: insight from the Leo Pargil dome, northwest India , 2013, Contributions to Mineralogy and Petrology.

[13]  E. Watson,et al.  Zircon saturation re-revisited , 2013 .

[14]  T. Harrison,et al.  The origin of Eo- and Neo-himalayan granitoids, Eastern Tibet , 2012 .

[15]  M. Wilson,et al.  The Himalayan leucogranites: Constraints on the nature of their crustal source region and geodynamic setting , 2012 .

[16]  P. Vermeesch On the visualisation of detrital age distributions , 2012 .

[17]  I. Buick,et al.  Isotopic variations in S-type granites: an inheritance from a heterogeneous source? , 2012, Contributions to Mineralogy and Petrology.

[18]  C. Spencer,et al.  Depositional provenance of the Himalayan metamorphic core of Garhwal region, India: Constrained by U–Pb and Hf isotopes in zircons , 2011 .

[19]  G. Gehrels,et al.  Detrital zircon geochronology of pre‐Tertiary strata in the Tibetan‐Himalayan orogen , 2011 .

[20]  M. Kohn,et al.  The lower Lesser Himalayan sequence: A Paleoproterozoic arc on the northern margin of the Indian plate , 2010 .

[21]  T. Holland,et al.  Burial and exhumation history of a Lesser Himalayan schist: Recording the formation of an inverted metamorphic sequence in NW India , 2007 .

[22]  R. Parrish,et al.  Correlation of lithotectonic units across the eastern Himalaya, Bhutan , 2006 .

[23]  J. Avouac,et al.  Mountain building in the Nepal Himalaya: Thermal and kinematic model , 2006 .

[24]  E. Draganits,et al.  Himalayan architecture constrained by isotopic tracers from clastic sediments , 2005 .

[25]  A. Tindle,et al.  The pressure–temperature–time path of migmatites from the Sikkim Himalaya , 2004 .

[26]  N. Harris,et al.  Fluid-enhanced melting during prograde metamorphism , 2001, Journal of the Geological Society.

[27]  J. Bunbury,et al.  Isotopic constraints on the structural relationships between the Lesser Himalayan Series and the High Himalayan Crystalline Series, Garhwal Himalaya , 2000 .

[28]  N. Harris,et al.  From sediment to granite: timescales of anatexis in the upper crust , 2000 .

[29]  J. Watson Fast, Simple Method of Powder Pellet Preparation for X-Ray Fluorescence Analysis , 1996 .

[30]  Michael H. Ramsey,et al.  An objective assessment of analytical method precision: comparison of ICP-AES and XRF for the analysis of silicate rocks , 1995 .

[31]  W. Griffin,et al.  THREE NATURAL ZIRCON STANDARDS FOR U‐TH‐PB, LU‐HF, TRACE ELEMENT AND REE ANALYSES , 1995 .

[32]  N. Harris,et al.  Decompression and anatexis of Himalayan metapelites , 1994 .

[33]  A. E. Patiño Douce,et al.  Phase equilibria and melt productivity in the pelitic system: implications for the origin of peraluminous granitoids and aluminous granulites , 1991 .

[34]  C. Deniel,et al.  Isotopic study of the Manaslu granite (Himalaya, Nepal): inferences on the age and source of Himalayan leucogranites , 1987 .

[35]  T. M. Harrison,et al.  Accessory minerals and the geochemical evolution of crustal magmatic systems: a summary and prospectus of experimental approaches , 1984 .

[36]  J. Kramers,et al.  Approximation of terrestrial lead isotope evolution by a two-stage model , 1975 .

[37]  K. Ludwig User's Manual for Isoplot 3.00 - A Geochronological Toolkit for Microsoft Excel , 2003 .