Application of Detrital Apatite U-Pb Geochronology and Trace Elements for Provenance Analysis, Insights from a Study on the Yarlung River Sand

Yufeng Du; Guangwei Li; Danyang Liu; Xianyan Wang; Dongxu Cai; Xiaolu Dong; Qi Yu

doi:10.1007/s12583-023-1863-x

Journal of Earth Science ›› 2024, Vol. 35 ›› Issue (4) : 1118-1129. DOI: 10.1007/s12583-023-1863-x

Article

Application of Detrital Apatite U-Pb Geochronology and Trace Elements for Provenance Analysis, Insights from a Study on the Yarlung River Sand

Author information +

History +

Abstract

Detrital U-bearing minerals (e.g., zircon, apatite) U-Pb ages with specific trace-element geochemistry, are frequently used in provenance analyses. In this study, we focus on the Yarlung River drainage in South Tibet, characterized by two distinct lithologic units: The Gangdese batholith to the north (mainly granitoids) and the Tethyan Himalaya (mainly sedimentary rocks) to the south, which plays a crucial role in the erosion of the Tibetan Plateau. To constrain the provenance of the Yarlung River Basin, we performed trace-element and U-Pb age analyses of detrital apatite from the river sands of the Yarlung River and its tributaries. Our findings indicate that the detrital apatite U-Pb age patterns of the north tributaries exhibit main peaks at approximately 40 and 60 Ma, consistent with the corresponding U-Pb age patterns of detrital zircon published. Further, their trace element casts fall mainly in the Type I granite region, also indicating the Gangdese arc-dominated source. However, those of the south tributaries (∼60–20 Ma) exhibit a different age distribution from the detrital zircon U-Pb groups (∼110–150, ∼500, and 1 100 Ma), suggesting that the detailed apatite U-Pb signals can provide excellent constraints on the provenance of igneous and metamorphic rock sources but less so for sedimentary rock sources. Combined with previous detrital zircon data in the study area, our detrital apatite information can highlight young metamorphic events from a complex background (i.e., Niyang and Nianchu rivers), which offers additional constraints on the provenance of the Yarlung River Basin. Generally, a combination of geochemistry and geochronology of multi-detrital heavy minerals, such as zircon and apatite, can provide powerful tools for provenance analysis.

Keywords

apatite / detrital apatite U-Pb age / trace elements / provenance analysis / Yarlung River / Tibetan Plateau / geochronology

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾

Yufeng Du, Guangwei Li, Danyang Liu, Xianyan Wang, Dongxu Cai, Xiaolu Dong, Qi Yu. Application of Detrital Apatite U-Pb Geochronology and Trace Elements for Provenance Analysis, Insights from a Study on the Yarlung River Sand. Journal of Earth Science, 2024, 35(4): 1118‒1129 https://doi.org/10.1007/s12583-023-1863-x

References

Publishing order | Descend order by publishing year | Descend order by cited within

[]	Aikman A B, Harrison T M, Lin D. Evidence for Early (> 44 Ma) Himalayan Crustal Thickening, Tethyan Himalaya, Southeastern Tibet. Earth and Planetary Science Letters, 2008, 274(1/2): 14-23

[]	Aitchison J C, Xia X P, Baxter A T, et al.. Detrital Zircon U–Pb Ages along the Yarlung-Tsangpo Suture Zone, Tibet: Implications for Oblique Convergence and Collision between India and Asia. Gondwana Research, 2011, 20(4): 691-709

[]	Amidon W H, Burbank D W, Gehrels G E. Construction of Detrital Mineral Populations: Insights from Mixing of U-Pb Zircon Ages in Himalayan Rivers. Basin Research, 2005, 17(4): 463-485

[]	Auden J B, Gansser A. Geology of the Himalayas. The Geographical Journal, 1967, 133(1): 84

[]	Belousova E, Griffin W, O’Reilly S Y, et al.. Igneous Zircon: Trace Element Composition as an Indicator of Source Rock Type. Contributions to Mineralogy and Petrology, 2002, 143(5): 602-622

[]	Burchfiel B C, Chen Z L, Hodges K V, et al.. The South Tibetan Detachment System, Himalayan Orogen: Extension Contemporaneous with and Parallel to Shortening in a Collisional Mountain Belt. Geological Society of America Special Papers, 1992, 269: 1-41

[]	Cai F L, Ding L, Laskowski A K, et al.. Late Triassic Paleogeographic Reconstruction along the Neo-Tethyan Ocean Margins, Southern Tibet. Earth and Planetary Science Letters, 2016, 435: 105-114

[]	Cai F L, Ding L, Yue Y H. Provenance Analysis of Upper Cretaceous Strata in the Tethys Himalaya, Southern Tibet: Implications for Timing of India-Asia Collision. Earth and Planetary Science Letters, 2011, 305(1/2): 195-206

[]	Carosi R, Montomoli C, Iaccarino S. 20 Years of Geological Mapping of the Metamorphic Core across Central and Eastern Himalayas. Earth-Science Reviews, 2018, 177: 124-138

[]	Carrapa B. Resolving Tectonic Problems by Dating Detrital Minerals. Geology, 2010, 38(2): 191-192

[]	Carrapa B, Faiz bin Hassim M, Kapp P A, et al.. Tectonic and Erosional History of Southern Tibet Recorded by Detrital Chronological Signatures along the Yarlung River Drainage. Geological Society of America Bulletin, 2017, 129(5/6): 570-581

[]	Chen Y, Li J G, Miao P S, et al.. U-Pb Ages and Hf Isotopes of Detrital Zircons from the Cretaceous Succession in the Southwestern Ordos Basin, Northern China: Implications for Provenance and Tectonic Evolution. Journal of Asian Earth Sciences, 2021, 219: 104896

[]	Chew D M, Petrus J A, Kamber B S. U-Pb LA-ICPMS Dating Using Accessory Mineral Standards with Variable Common Pb. Chemical Geology, 2014, 363: 185-199

[]	Chew D M, Spikings R A. Apatite U-Pb Thermochronology: A Review. Minerals, 2021, 11(10): 1095

[]	Chew D M, Sylvester P J, Tubrett M N. U-Pb and Th-Pb Dating of Apatite by LA-ICPMS. Chemical Geology, 2011, 280(1/2): 200-216

[]	Chew D, O’Sullivan G, Caracciolo L, et al.. Sourcing the Sand: Accessory Mineral Fertility, Analytical and Other Biases in Detrital U-Pb Provenance Analysis. Earth Science Reviews, 2020, 202: 103093

[]	Chu M F, Chung S L, Song B, et al.. Zircon U-Pb and Hf Isotope Constraints on the Mesozoic Tectonics and Crustal Evolution of Southern Tibet. Geology, 2006, 34(9): 745-748

[]	Chung S L, Chu M F, Zhang Y Q, et al.. Tibetan Tectonic Evolution Inferred from Spatial and Temporal Variations in Post-Collisional Magmatism. Earth-Science Reviews, 2005, 68(3/4): 173-196

[]	Cina S E, Yin A, Grove M, et al.. Gangdese Arc Detritus within the Eastern Himalayan Neogene Foreland Basin: Implications for the Neogene Evolution of the Yalu-Brahmaputra River System. Earth and Planetary Science Letters, 2009, 285(1/2): 150-162

[]	Dai J G, Wang C S, Hourigan J, et al.. Exhumation History of the Gangdese Batholith, Southern Tibetan Plateau: Evidence from Apatite and Zircon (U-Th)/He Thermochronology. The Journal of Geology, 2013, 121(2): 155-172

[]	DeCelles P G, Gehrels G E, Najman Y, et al.. Detrital Geochronology and Geochemistry of Cretaceous-Early Miocene Strata of Nepal: Implications for Timing and Diachroneity of Initial Himalayan Orogenesis. Earth and Planetary Science Letters, 2004, 227(3/4): 313-330

[]	DeCelles P G, Gehrels G E, Quade J, et al.. Tectonic Implications of U-Pb Zircon Ages of the Himalayan Orogenic Belt in Nepal. Science, 2000, 288(5465): 497-499

[]	DeCelles P G, Kapp P, Gehrels G E, et al.. Paleocene – Eocene Foreland Basin Evolution in the Himalaya of Southern Tibet and Nepal: Implications for the Age of Initial India-Asia Collision. Tectonics, 2014, 33(5): 824-849

[]	Di Giulio A, Ronchi A, Sanfilippo A, et al.. Detrital Zircon Provenance from the Neuquén Basin (South-Central Andes): Cretaceous Geodynamic Evolution and Sedimentary Response in a Retroarc-Foreland Basin. Geology, 2012, 40(6): 559-562

[]	Dickinson W R. Impact of Differential Zircon Fertility of Granitoid Basement Rocks in North America on Age Populations of Detrital Zircons and Implications for Granite Petrogenesis. Earth and Planetary Science Letters, 2008, 275(1/2): 80-92

[]	Eggins S M, Shelley J M G. Compositional Heterogeneity in NIST SRM 610–617 Glasses. Geostandards Newsletter, 2002, 26(3): 269-286

[]	Enkelmann E, Ehlers T A, Zeitler P K, et al.. Denudation of the Namche Barwa Antiform, Eastern Himalaya. Earth and Planetary Science Letters, 2011, 307(3/4): 323-333

[]	Garzanti E, Baud A, Mascle G. Sedimentary Record of the Northward Flight of India and Its Collision with Eurasia (Ladakh Himalaya, India). Geodinamica Acta, 1987, 1(4/5): 297-312

[]	Garzanti E, Fort P, Sciunnach D. First Report of Lower Permian Basalts in South Tibet: Tholeiitic Magmatism during Break-up and Incipient Opening of Neotethys. Journal of Asian Earth Sciences, 1999, 17(4): 533-546

[]

Garzanti

, Limonta

, Vezzoli

, et al.. Ingersoll

R V

, Lawton

T F

, Graham

S A

, et al.. Petrology and Multimineral Fingerprinting of Modern Sand Generated from a Dissected Magmatic Arc (Lhasa River, Tibet). Geological Society of America: Tectonics, Sedimentary Basins, and Provenance: A Celebration of the Career of William R. Dickinson, 2018

[]	Garzanti E, Vermeesch P, Andò S, et al.. Provenance and Recycling of Arabian Desert Sand. Earth Science Reviews, 2013, 120: 1-19

[]	Gehrels G E, Yin A, Wang X F. Detrital-Zircon Geochronology of the Northeastern Tibetan Plateau. Geological Society of America Bulletin, 2003, 115(7): 881-896

[]	Gehrels G, Kapp P, DeCelles P, et al.. Detrital Zircon Geochronology of Pre-Tertiary Strata in the Tibetan-Himalayan Orogen. Tectonics, 2011, 30(5): TC5016

[]	Goscombe B, Gray D, Foster D A. Metamorphic Response to Collision in the Central Himalayan Orogen. Gondwana Research, 2018, 57: 191-265

[]	Grimes C B, John B E, Kelemen P B, et al.. Trace Element Chemistry of Zircons from Oceanic Crust: A Method for Distinguishing Detrital Zircon Provenance. Geology, 2007, 35(7): 643-646

[]	Guo R H, Hu X M, Garzanti E, et al.. How Faithfully do the Geochronological and Geochemical Signatures of Detrital Zircon, Titanite, Rutile and Monazite Record Magmatic and Metamorphic Events? A Case Study from the Himalaya and Tibet. Earth Science Reviews, 2020, 201: 103082

[]	Harrison T M, Grove M, Lovera O M, et al.. A Model for the Origin of Himalayan Anatexis and Inverted Metamorphism. Journal of Geophysical Research: Solid Earth, 1998, 103(B11): 27017-27032

[]	Harrison T M, Yin A, Grove M, et al.. The Zedong Window: A Record of Superposed Tertiary Convergence in Southeastern Tibet. Journal of Geophysical Research: Solid Earth, 2000, 105(B8): 19211-19230

[]	Hawkesworth C, Cawood P, Kemp T, et al.. Geochemistry: A Matter of Preservation. Science, 2009, 323(5910): 49-50

[]	Hu D G, Wu Z H, Jiang W, et al.. SHRIMP Zircon U-Pb Age and Nd Isotopic Study on the Nyainqêntanglha Group in Tibet. Science in China Series D: Earth Sciences, 2005, 48(9): 1377-1386

[]	Hu X M, Garzanti E, Moore T, et al.. Direct Stratigraphic Dating of India-Asia Collision Onset at the Selandian (Middle Paleocene, 59 ± 1 Ma). Geology, 2015, 43(10): 859-862

[]	Hu X M, Garzanti E, Wang J G, et al.. The Timing of India-Asia Collision Onset-Facts, Theories, Controversies. Earth-Science Reviews, 2016, 160: 264-299

[]	Hu X M, Jansa L, Chen L, et al.. Provenance of Lower Cretaceous Wölong Volcaniclastics in the Tibetan Tethyan Himalaya: Implications for the Final Breakup of Eastern Gondwana. Sedimentary Geology, 2010, 223(3/4): 193-205

[]	Iizuka T, Hirata T, Komiya T, et al.. U-Pb and Lu-Hf Isotope Systematics of Zircons from the Mississippi River Sand: Implications for Reworking and Growth of Continental Crust. Geology, 2005, 33(6): 485-488

[]	Ji W Q, Wu F Y, Chung S L, et al.. Zircon U-Pb Geochronology and Hf Isotopic Constraints on Petrogenesis of the Gangdese Batholith, Southern Tibet. Chemical Geology, 2009, 262(3/4): 229-245

[]	Kohn M J. Himalayan Metamorphism and Its Tectonic Implications. Annual Review of Earth and Planetary Sciences, 2014, 42(1): 381-419

[]	Le Fort P. Himalayas: The Collided Range. Present Knowledge of the Continental Arc. American Journal of Science, 1975, 275A: 1-44

[]	Lee H Y, Chung S L, Lo C H, et al.. Eocene Neotethyan Slab Breakoff in Southern Tibet Inferred from the Linzizong Volcanic Record. Tectonophysics, 2009, 477(1/2): 20-35

[]	Lee J, Hacker B R, Dinklage W S, et al.. Evolution of the Kangmar Dome, Southern Tibet: Structural, Petrologic, and Thermochronologic Constraints. Tectonics, 2000, 19(5): 872-895

[]	Lee J, Hacker B, Wang Y. Evolution of North Himalayan Gneiss Domes: Structural and Metamorphic Studies in Mabja Dome, Southern Tibet. Journal of Structural Geology, 2004, 26(12): 2297-2316

[]	Leier A L, DeCelles P G, Kapp P, et al.. Lower Cretaceous Strata in the Lhasa Terrane, Tibet, with Implications for Understanding the Early Tectonic History of the Tibetan Plateau. Journal of Sedimentary Research, 2007, 77(10): 809-825

[]	Leier A L, Kapp P, Gehrels G E, et al.. Detrital Zircon Geochronology of Carboniferous? Cretaceous Strata in the Lhasa Terrane, Southern Tibet. Basin Research, 2007, 19(3): 361-378

[]	Li G W, Kohn B, Sandiford M, et al.. Post-Collisional Exhumation of the Indus-Yarlung Suture Zone and Northern Tethyan Himalaya, Saga, SW Tibet. Gondwana Research, 2018, 64: 1-10

[]	Li G W, Sandiford M, Boger S, et al.. Provenance of the Upper Cretaceous to Lower Tertiary Sedimentary Relicts in the Renbu Mélange Zone, within the Indus-Yarlung Suture Zone. The Journal of Geology, 2015, 123(1): 39-54

[]	Li Z Q, Li F J, Chen Z A, et al.. Provenance of Late Mesozoic Strata and Tectonic Implications for the Southwestern Ordos Basin, North China: Evidence from Detrital Zircon U-Pb Geochronology and Hf Isotopes. Journal of Earth Science, 2022, 33(2): 373-394

[]	Malusà M G, Resentini A, Garzanti E. Hydraulic Sorting and Mineral Fertility Bias in Detrital Geochronology. Gondwana Research, 2016, 31: 1-19

[]	McQuarrie N, Robinson D, Long S A, et al.. Preliminary Stratigraphic and Structural Architecture of Bhutan: Implications for the along Strike Architecture of the Himalayan System. Earth and Planetary Science Letters, 2008, 272(1/2): 105-117

[]	Molnar P, Boos W R, Battisti D S. Orographic Controls on Climate and Paleoclimate of Asia: Thermal and Mechanical Roles for the Tibetan Plateau. Annual Review of Earth and Planetary Sciences, 2010, 38: 77-102

[]	Myrow P M, Hughes N C, Searle M P, et al.. Stratigraphic Correlation of Cambrian - Ordovician Deposits along the Himalaya: Implications for the Age and Nature of Rocks in the Mount Everest Region. Geological Society of America Bulletin, 2009, 121(3/4): 323-332

[]	O’Sullivan G J, Chew D M, Morton A C, et al.. An Integrated Apatite Geochronology and Geochemistry Tool for Sedimentary Provenance Analysis. Geochemistry, Geophysics, Geosystems, 2018, 19(4): 1309-1326

[]	O’Sullivan G J, Chew D M, Kenny G, et al.. The Trace Element Composition of Apatite and Its Application to Detrital Provenance Studies. Earth-Science Reviews, 2020, 201: 103044

[]	Olierook H K H, Barham M, Fitzsimons I C W, et al.. Tectonic Controls on Sediment Provenance Evolution in Rift Basins: Detrital Zircon U-Pb and Hf Isotope Analysis from the Perth Basin, Western Australia. Gondwana Research, 2019, 66: 126-142

[]	Palin R M, Searle M P, St-Onge M R, et al.. Monazite Geochronology and Petrology of Kyanite- and Sillimanite-Grade Migmatites from the Northwestern Flank of the Eastern Himalayan Syntaxis. Gondwana Research, 2014, 26(1): 323-347

[]	Pan G T, Ding J, Yao D S, et al.. . Geological Map of Qinghai-Xizang (Tibetan) Plateau and Adjacent Areas (1:1 500 000), 2004 Chengdu Chengodu Carogaphic Patbishng House 1-133 (in Chinese)

[]	Paton C, Hellstrom J, Paul B, et al.. Iolite: Freeware for the Visualisation and Processing of Mass Spectrometric Data. Journal of Analytical Atomic Spectrometry, 2011, 26(12): 2508-2518

[]	Petrus J A, Kamber B S. VizualAge: A Novel Approach to Laser Ablation ICP-MS U-Pb Geochronology Data Reduction. Geostandards and Geoanalytical Research, 2012, 36(3): 247-270

[]	Ratschbacher L, Frisch W, Liu G H, et al.. Distributed Deformation in Southern and Western Tibet during and after the India-Asia Collision. Journal of Geophysical Research: Solid Earth, 1994, 99(B10): 19917-19945

[]	Rubatto D. Zircon Trace Element Geochemistry: Partitioning with Garnet and the Link between U-Pb Ages and Metamorphism. Chemical Geology, 2002, 184(1/2): 123-138

[]	Schoene B, Bowring S A. U-Pb Systematics of the McClure Mountain Syenite: Thermochronological Constraints on the Age of the ⁴⁰Ar/³⁹Ar Standard MMHB. Contributions to Mineralogy and Petrology, 2006, 151(5): 615-630

[]	Sciunnach D, Garzanti E. Subsidence History of the Tethys Himalaya. Earth Science Reviews, 2012, 111(1/2): 179-198

[]	Smit M A, Hacker B R, Lee J. Tibetan Garnet Records Early Eocene Initiation of Thickening in the Himalaya. Geology, 2014, 42(7): 591-594

[]	Spencer C J, Kirkland C L, Roberts N M W. Implications of Erosion and Bedrock Composition on Zircon Fertility: Examples from South America and Western Australia. Terra Nova, 2018, 30(4): 289-295

[]	Stewart R J, Hallet B, Zeitler P K, et al.. Brahmaputra Sediment Flux Dominated by Highly Localized Rapid Erosion from the Easternmost Himalaya. Geology, 2008, 36(9): 711-714

[]	Sylvester P J. Laser Ablation-ICP-MS in the Earth Sciences Current Practices and Outstanding Issues. Mineralogical Association of Canada Short Course, 2008, 40: 1-348

[]	Thomson S N, Gehrels G E, Ruiz J, et al.. Routine Low-Damage Apatite U-Pb Dating Using Laser Ablation-Multicollector-ICPMS. Geochemistry, Geophysics, Geosystems, 2012, 13(2): Q0AA21

[]	Turzewski M D, Huntington K W, Licht A, et al.. Provenance and Erosional Impact of Quaternary Megafloods through the Yarlung-Tsangpo Gorge from Zircon U-Pb Geochronology of Flood Deposits, Eastern Himalaya. Earth and Planetary Science Letters, 2020, 535: 116113

[]	Vermeesch P. On the Visualisation of Detrital Age Distributions. Chemical Geology, 2012, 312/313: 190-194

[]	Wen D R, Liu D, Chung S L, et al.. Zircon SHRIMP U-Pb Ages of the Gangdese Batholith and Implications for Neotethyan Subduction in Southern Tibet. Chemical Geology, 2008, 252(3/4): 191-201

[]	Xiang D F, Zhang Z Y, Zack T, et al.. Apatite U-Pb Dating with Common Pb Correction Using LA-ICP-MS/MS. Geostandards and Geoanalytical Research, 2021, 45(4): 621-642

[]	Yin A, Dubey C S, Kelty T K, et al.. Structural Evolution of the Arunachal Himalaya and Implications for Asymmetric Development of the Himalayan Orogen. Current Science, 2006, 90(2): 195-206

[]	Zeng L S, Gao L F, Xie K J, et al.. Mid-Eocene High Sr/Y Granites in the Northern Himalayan Gneiss Domes: Melting Thickened Lower Continental Crust. Earth and Planetary Science Letters, 2011, 303(3/4): 251-266

[]

Zhang

J Y

, Yin

, Liu

W C

, et al.. Coupled U-Pb Dating and Hf Isotopic Analysis of Detrital Zircon of Modern River Sand from the Yalu River (Yarlung Tsangpo) Drainage System in Southern Tibet: Constraints on the Transport Processes and Evolution of Himalayan Rivers. Geological Society of America Bulletin, 2012, 124(9/10): 1449-1473

[]	Zhang Z M, Ding H X, Dong X, et al.. Formation and Evolution of the Gangdese Magmatic Arc, Southern Tibet. Acta Petrologica Sinica, 2019, 35(2): 275-294

[]	Zhang Z M, Ding H X, Palin R M, et al.. The Lower Crust of the Gangdese Magmatic Arc, Southern Tibet, Implication for the Growth of Continental Crust. Gondwana Research, 2020, 77: 136-146

[]	Zhang Z M, Dong X, Xiang H, et al.. Reworking of the Gangdese Magmatic Arc, Southeastern Tibet: Post-Collisional Metamorphism and Anatexis. Journal of Metamorphic Geology, 2015, 33(1): 1-21

[]	Zhu D C, Chung S L, Mo X X, et al.. The 132 Ma Comei-Bunbury Large Igneous Province: Remnants Identified in Present-Day Southeastern Tibet and Southwestern Australia. Geology, 2009, 37(7): 583-586

[]	Zhu D C, Pan G T, Mo X X, et al.. Petrogenesis of Volcanic Rocks in the Sangxiu Formation, Central Segment of Tethyan Himalaya: A Probable Example of Plume-Lithosphere Interaction. Journal of Asian Earth Sciences, 2007, 29(2/3): 320-335

[]	Zhu D C, Wang Q, Chung S L, et al.. Gangdese Magmatism in Southern Tibet and India-Asia Convergence since 120 Ma. Geological Society, London, Special Publications, 2019, 483(1): 583-604