First Record of Middle Eocene Elephant Ancestors’ Footprints in the Gonjo Basin, East Tibet Plateau

Asma Tahir; Huazhou Yao; Junaid Khan; Yangui Li; He Zhao; Yue Yu; Tang Yuan

doi:10.1007/s12583-023-1946-6

Journal of Earth Science ›› 2024, Vol. 35 ›› Issue (4) : 1224-1235. DOI: 10.1007/s12583-023-1946-6

Article

First Record of Middle Eocene Elephant Ancestors’ Footprints in the Gonjo Basin, East Tibet Plateau

Asma Tahir¹^,² ,
Huazhou Yao¹^,²^,^b ,
Junaid Khan¹^,² ,
Yangui Li¹^,² ,
He Zhao³ ,
Yue Yu⁵ ,
Tang Yuan⁴

Author information +

History +

Abstract

It is the first time that the fossil footprints of a group of Middle Eocene elephant ancestors have been discovered in the Gonjo Basin, East Tibet Plateau. The Gonjo Formation is attributed to the Middle Eocene Epoch (U-Pb age = 44.7 ± 1.2 Ma) and consists mainly of purplish-red, medium- to coarse-grained sandstones, siltstones interbedded with mudstones, and conglomerates with sedimentary structures like ripple marks, rip-up clasts, and trough-cross bedding, suggesting fluvial-lacustrine systems. The group of fossil footprints has a characteristic oval-concave shape, and the toe impressions are absent. Some fossil footprints are overstepped with a pockmarked texture resembling Proboscipeda enigmatica. More than 165 fossil footprints of the group are relatively well-preserved with different diameters, which is evidence of highly social behavior and trackmakers of different ages, including calves, juveniles, adolescents, and adults. The size frequency of the fossil footprints enabled us to deduce the body mass, shoulder height, and hip-height distribution of the trackmakers that crossed the East Tibet Plateau 44.7 Ma ago. The trackmakers comprised an estimated average hip-height of 111.8 cm, an average shoulder height of 172.8 cm for males/155.9 cm for females, and an average body mass of approximately 1 218.1 kg for males/907.8 kg for females. The abundance of fossil footprints reveals that in the Middle Eocene Epoch, the environment was extraordinarily conducive for the elephant ancestors to live in the East Tibet region.

Keywords

Proboscipeda enigmatica / East Tibet Plateau / Gonjo Formation / fossil footprints / fluvial-lacustrine

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Asma Tahir, Huazhou Yao, Junaid Khan, Yangui Li, He Zhao, Yue Yu, Tang Yuan. First Record of Middle Eocene Elephant Ancestors’ Footprints in the Gonjo Basin, East Tibet Plateau. Journal of Earth Science, 2024, 35(4): 1224‒1235 https://doi.org/10.1007/s12583-023-1946-6

References

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

[]	Abbassi N, Alinasiri S, Lucas S G. New Localities of Late Eocene Vertebrate Footprints from the Tarom Mountains, Northwestern Iran. Historical Biology, 2017, 29(7): 987-1006.

[]	Abbassi N, Lucas S G, Zaare G R. First Report of Oligocene Vertebrate Footprints from Iran. Palaeogeography, Palaeoclimatology, Palaeoecology, 2015, 440:78-89.

[]	Aitchison J C, Davis A M. When did the India—Asia Collision Really Happen?. Gondwana Research, 2001, 4(4): 560-561.

[]	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.

[]	Alexander R M. Estimates of Speeds of Dinosaurs. Nature, 1976, 261:129-130.

[]	An Z S, Kutzbach J E, Prell W L, et al. Evolution of Asian Monsoons and Phased Uplift of the Himalaya-Tibetan Plateau since Late Miocene Times. Nature, 2001, 411(6833): 62-66.

[]	Aramayo S A, Manera de Bianco T, Bastianelli N V, et al. Pehuen Co: Updated Taxonomic Review of a Late Pleistocene Ichnological Site in Argentina. Palaeogeography, Palaeoclimatology, Palaeoecology, 2015, 439:144-165.

[]	Ataabadi M M, Sarjeant W A S. Eocene Mammal Footprints from Eastern Iran: a Preliminary Study. Comptes Rendus De L’Académie Des Sciences - Series IIA: Earth and Planetary Science, 2000, 331(8): 543-547.

[]	Athanassiou A. A Skeleton of Mammuthus Trogontherii (Proboscidea, Elephantidae) from NW Peloponnese, Greece. Quaternary International, 2012, 255:9-28.

[]	Barnosky A D, Matzke N, Tomiya S, et al. Has the Earth’s Sixth Mass Extinction Already Arrived?. Nature, 2011, 471(7336): 51-57.

[]	Bennett M R, Bustos D, Belvedere M, et al. Soft-Sediment Deformation below Mammoth Tracks at White Sands National Monument (New Mexico) with Implications for Biomechanical Inferences from Tracks. Palaeogeography, Palaeoclimatology, Palaeoecology, 2019, 527:25-38.

[]	Berggren W A. Cenozoic Era. Encyclopedia Britannica, 2020

[]	Brugal J-P, Raposo L. Foz do Enxarrique (Ródao, Portugal): Preliminary Results of the Analysis of a Bone Assemblage from a Middle Palaeolithic Open Site. Monographie des RömischGermanischen Zentralmuseums, 1999, 42:367-379.

[]	Chen D, Jiang F J, Pang X Q, et al. Middle Eocene Terrestrial Paleoweathering and Climate Evolution in the Midlatitude Bohai Bay Basin of Eastern China. Petroleum Science, 2023, 20(3): 1471-1487.

[]	Christiansen P. Body Size in Proboscideans, with Notes on Elephant Metabolism. Zoological Journal of the Linnean Society, 2004, 140(4): 523-549.

[]	Chung S L, Lo C H, Lee T Y, et al. Diachronous Uplift of the Tibetan Plateau Starting 40? Myr ago. Nature, 1998, 394(6695): 769-773.

[]	Damuth J D, MacFadden B J. Body Size in Mammalian Paleobiology: Estimation and Biological Implications, 1990 Cambridge Cambridge University Press

[]	Della Rocca F. How Tall is an Elephant? Two Methods for Estimating Elephant Height. Web Ecology, 2007, 7(1): 1-10.

[]	Ding L, Kapp P, Wan X Q. Paleocene - Eocene Record of Ophiolite Obduction and Initial India-Asia Collision, South Central Tibet. Tectonics, 2005, 24(3): TC3001

[]	Ding L, Maksatbek S, Cai F L, et al. Processes of Initial Collision and Suturing between India and Asia. Science China Earth Sciences, 2017, 60(4): 635-651.

[]	Dos Reis M, Donoghue P C J, Yang Z H. Neither Phylogenomic nor Palaeontological Data Support a Palaeogene Origin of Placental Mammals. Biology Letters, 2014, 10(1): 20131003

[]	Douglas-Hamilton I. On the Ecology and Behavior of the African Elephant, 1972 Oxford University of Oxford

[]	Dupont-Nivet G, Hoorn C, Konert M. Tibetan Uplift Prior to the Eocene-Oligocene Climate Transition: Evidence from Pollen Analysis of the Xining Basin. Geology, 2008, 36(12): 987

[]	Ellenberger P. Sur les Empreintes de pas des Gros Mammiferes de L’EOCENE Superieur de Garrigues-Ste-Eulalie (Gard). Pascal and Francis Bibliographic Databases, 1980 37 78 (2024-04-02)

[]	England P, Searle M. The Cretaceous-Tertiary Deformation of the Lhasa Block and Its Implications for Crustal Thickening in Tibet. Tectonics, 1986, 5(1): 1-14.

[]	Farina R A, Vizcaino S F, Bargo M S. Body Mass Estimations in Lujanian (Late Pleistocene – Early Holocene of South America) Mammal Megafauna. Mastozoologia Neotropical, 1998, 5(2): 87-108.

[]	Gheerbrant E. Paleocene Emergence of Elephant Relatives and the Rapid Radiation of African Ungulates. Proceedings of the National Academy of Sciences of the United States of America, 2009, 106(26): 10717-10721.

[]	Gheerbrant E, Sudre J, Cappetta H. A Palaeocene Proboscidean from Morocco. Nature, 1996, 383:68-70.

[]	Gheerbrant E, Sudre J, Cappetta H, et al. A New Large Mammal from the Ypresian of Morocco: Evidence of Surprising Diversity of Early Proboscideans. Acta Palaeontologica Polonica, 2002, 47(3): 493-506.

[]	Gu H O, Xiao Y L, Santosh M, et al. Spatial and Temporal Distribution of Mesozoic Adakitic Rocks along the Tan-Lu Fault, Eastern China: Constraints on the Initiation of Lithospheric Thinning. Lithos, 2013, 177:352-365.

[]	Hamblin A H, Sarjeant W A, Spalding D A. Vertebrate Footprints in the Duchesne River and Uinta Formations (Middle to Late Eocene), Uinta Basin, Utah. Utah Geol. Surv. Misc. Publ., 1999, 99(1): 443-454.

[]	Hamblin A, Sarjeant W, Spalding D. A Remarkable Mammal Trackway in the Unita Formation (Late Eocene) of Utah. Brigham Young University Geology Studies, 1998, 43:9-18.

[]	Hanks J. Growth of the African Elephant (Loxodonta Africana). African Journal of Ecology, 1972, 10(4): 251-272.

[]	Haynes G. Mammoths, Mastodonts, and Elephants: Biology, Behavior and the Fossil Record, 1991 Cambridge Cambridge University Press

[]	Horton B K, Yin A, Spurlin M S, et al. Paleocene – Eocene Syncontractional Sedimentation in Narrow, Lacustrine-Dominated Basins of East-Central Tibet. Geological Society of America Bulletin, 2002, 114(7): 771-786.

[]	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.

[]	Hutchinson J R, Delmer C, Miller C E, et al. From Flat Foot to Fat Foot: Structure, Ontogeny, Function, and Evolution of Elephant “Sixth Toes”. Science, 2011, 334(6063): 1699-1703.

[]	Kingsolver J G, Huey R B. Size, Temperature, and Fitness: Three Rules. Evolutionary Ecology Research, 2008, 10(2): 251-268.

[]	Kutzbach J E, Guetter P J, Ruddiman W F, et al. Sensitivity of Climate to Late Cenozoic Uplift in Southern Asia and the American West: Numerical Experiments. Journal of Geophysical Research: Atmospheres, 1989, 94(D15): 18393-18407.

[]	Larramendi A. Skeleton of a Late Pleistocene Steppe Mammoth (Mammuthus Trogontherii) from Zhalainuoer, Inner Mongolian Autonomous Region, China. Paläontologische Zeitschrift, 2014, 89(2): 229-250.

[]	Larramendi A. Proboscideans: Shoulder Height, Body Mass and Shape. Acta Palaeontologica Polonica, 2015, 61(3): 537-574.

[]	Larramendi A. Skeleton of a Late Pleistocene Steppe Mammoth (Mammuthus trogontherii) from Zhalainuoer, Inner Mongolian Autonomous Region, China. Paläontologische Zeitschrift, 2015, 89(2): 229-250.

[]	Larramendi A, Palombo M R, Marano F. Reconstructing the Life Appearance of a Pleistocene Giant: Size, Shape, Sexual Dimorphism and Ontogeny of Palaeoloxodon Antiquus (Proboscidea: Elephantidae) from Neumark-Nord 1 (Germany). Boll. Soc. Paleont. Italiana, 2017, 56(3): 299-317.

[]	Laws R M, Parker I S C, Johnstone R C B. Elephants and Their Habitats: The Ecology of Elephants in North Bunyoro, Uganda, 1975 Oxford Oxford University Press

[]	Laws R, Parker I. Recent Studies on Elephant Populations in East Africa. Symp. Zool. Soc. Lond., 1968, 21:319-359.

[]	Lee P C, Moss C J. Statural Growth in Known-Age African Elephants (Loxodonta Africana). Journal of Zoology, 1995, 236(1): 29-41.

[]	Leuthold W. Group Size in Elephants of Tsavo National Park and Possible Factors Influencing It. The Journal of Animal Ecology, 1976, 45(2): 425-439.

[]	Li C. A Review on 20 Years’ Study of the Longmu Co-Shuanghu-Lancang River Suture Zone in Qinghai-Xizang (Tibet) Plateau. Geological Review, 2008, 54(1): 105 119 (in Chinese with English Abstract)

[]	Li J X, Qin K Z, Li G M, et al. Post-Collisional Ore-Bearing Adakitic Porphyries from Gangdese Porphyry Copper Belt, Southern Tibet: Melting of Thickened Juvenile Arc Lower Crust. Lithos, 2011, 126(3/4): 265-277.

[]	Li S H, van Hinsbergen D J J, Najman Y, et al. Does Pulsed Tibetan Deformation Correlate with Indian Plate Motion Changes?. Earth and Planetary Science Letters, 2020, 536:116144

[]	Li Z X, Chen Z L, Li X Z, et al. K-Ar Ages of Cenozoic Volcanic Rocks from Gongjue Basin in Eastern Tibet. Earth Science, 2004, 29(3): 278 282 (in Chinese with English Abstract)

[]	Lister A M. Epiphyseal Fusion and Postcranial Age Determination in the Woolly Mammoth, Mammuthus Primigenius (Blum.). Deinsea, 1999, 6(1): 79-88.

[]	Liu X D, Yin Z Y. Sensitivity of East Asian Monsoon Climate to the Uplift of the Tibetan Plateau. Palaeogeography, Palaeoclimatology, Palaeoecology, 2002, 183(3/4): 223-245.

[]	Liu Y S, Hu Z C, Gao S, et al. In Situ Analysis of Major and Trace Elements of Anhydrous Minerals by LA-ICP-MS without Applying an Internal Standard. Chemical Geology, 2008, 257(1/2): 34-43.

[]	Lockley M G, Hunt A P. Dinosaur Tracks and Other Fossil Footprints of the Western United States: New York, 1995 Columbia Columbia University Press

[]	Lockley M G, Meyer C. Dinosaur Tracks and Other Fossil Footprints of Europe: New York, 1999 Columbia Columbia University Press

[]	Lockley M G, Ritts B D, Leonardi G. Mammal Track Assemblages from the Early Tertiary of China, Peru, Europe and North America. Palaios, 1999, 14(4): 398-404.

[]	MacLeod K G, Quinton P C, Sepúlveda J, et al. Postimpact Earliest Paleogene Warming Shown by Fish Debris Oxygen Isotopes (El Kef, Tunisia). Science, 2018, 360(6396): 1467-1469.

[]	Manning P L. A New Approach to the Analysis and Interpretation of Tracks: Examples from the Dinosauria. Geological Society, London, Special Publications, 2004, 228(1): 93-123.

[]	McNab B K. Damuth J, MacFadden B J. The Physiological Significance of Body Size. Body Size in Mammalian Paleobiology: Estimation and Biological Implications, 1990 Cambridge Cambridge University Press 11-23.

[]	McNeil P, Hills L V, Tolman M S, et al. Significance of Latest Pleistocene Tracks, Trackways, and Trample Grounds from Southern Alberta, Canada. Cenozoic Vertebrate Tracks and Traces, 2007, 42:209-233.

[]	McNeil P, Hills L, Kooyman B, et al. Mammoth Tracks Indicate a Declining Late Pleistocene Population in Southwestern Alberta, Canada. Quaternary Science Reviews, 2005, 24(10/11): 1253-1259.

[]	Merz G. Movement Patterns and Group Size of the African Forest Elephant Loxodonta Africana Cyclotis in the Tai National Park, Ivory Coast. African Journal of Ecology, 1986, 24(2): 133-136.

[]	Mihlbachler M C, Lucas S G, Emry R J, et al. A New Brontothere (Brontotheriidae, Perissodactyla, Mammalia) from the Eocene of the Ily Basin of Kazakstan and a Phylogeny of Asian “Horned” Brontotheres. American Museum Novitates, 2004, 3439(1): 1

[]	Molnar P, Tapponnier P. Cenozoic Tectonics of Asia: Effects of a Continental Collision: Features of Recent Continental Tectonics in Asia can be Interpreted as Results of the India-Eurasia Collision. Science, 1975, 189(4201): 419-426.

[]	Moss C, Poole J. Hinde R A. Relationships and Social Structure of African Elephants. Primate Social Relationships: An Integrated Approach, 1983 Oxford Blackwells 315-325.

[]	Mughal M S, Zhang C J, Hussain A, et al. Petrogenesis and Geochronology of Tianshui Granites from Western Qinling Orogen, Central China: Implications for Caledonian and Indosinian Orogenies on the Asian Plate. Minerals, 2020, 10(6): 515

[]	Muñiz F, Cáceres L M, Rodríguez-Vidal J, et al. Following the Last Neanderthals, Mammal Tracks in Late Pleistocene Coastal Dunes of Gibraltar (S Iberian Peninsula). Quaternary Science Reviews, 2019, 217:297-309.

[]	Murphy M A, Yin A, Harrison T M, et al. Did the Indo-Asian Collision Alone Create the Tibetan Plateau?. Geology, 1997, 25(8): 719-722.

[]	Neto de Carvalho C, Belaústegui Z, Toscano A, et al. First Tracks of Newborn Straight-Tusked Elephants (Palaeoloxodon Antiquus). Scientific Reports, 2021, 11(1): 17311

[]	Neto de Carvalho C, Figueiredo S, et al. Vertebrate Tracks and Trackways from the Pleistocene Eolianites of SW Portugal. Comunicações Geológica, 2016, 103:101-116.

[]	Ni X J, Li Q, Zhang C, et al. Paleogene Mammalian Fauna Exchanges and the Paleogeographic Pattern in Asia. Science China Earth Sciences, 2020, 63(2): 202-211.

[]	O’Leary M A, Bloch J I, Flynn J J, et al. The Placental Mammal Ancestor and the Post-K-Pg Radiation of Placentals. Science, 2013, 339(6120): 662-667.

[]	Osborn H F. Evolution and Geographic Distribution of the Proboscidea: Moeritheres, Deinotheres and Mastodonts. Journal of Mammalogy, 1934, 15(3): 177-184.

[]	Osborn H F. Proboscidea: Moeritherioidea, Deinotherioidea, Mastodontoidea, 1936 New York The American Museum Press

[]	Osborn H F. Proboscidea: Stegodontoidea, Elephantoidea, 1942 New York American Museum of Natural History 805-1675.

[]

Palombo

M R

, Giovinazzo

. Elephas Falconeri from Spinagallo Cave (South-Eastern Sicily, Hyblean Plateau, Siracusa): A Preliminary Report on Brain to Body Weight Comparison. Proceedings of the International Symposium “Insular Vertebrate Evolution: The Palaeontological Approach”, September 16–19, 2005, Mallorca, 2005 255-264.

[]	Palombo M R, Panarello A, Mietto P. Did Elephants Meet Humans along the Devil’s Path? A Preliminary Report. Alpine and Mediterranean Quaternary, 2018, 31:83-87.

[]	Pan G T, Ding J, Yao D S, et al. Instruction of the Geological Map of Qinghai-Tibet Plateau and Its Adjacent Regions, 2004 Chengdu Chengdu Cartographic Publishing House (in Chinese)

[]	Panera J, Rubio-Jara S, Yravedra J, et al. Manzanares Valley (Madrid, Spain): A Good Country for Proboscideans and Neanderthals. Quaternary International, 2014, 326/327:329-343.

[]	Panin N, Avram E. Noe Urme de pas de Vertebrate in Miocenul Subcarpatilor Ruminestkya. Studie si Cercetari de Gélogie, Géophyzica, si Géografie, Serie de Géologie, 1962, 7:455-484.

[]	Pasenko M R. Quantitative and Qualitative Data of Footprints Produced by Asian (Elephas Maximus) and African (Loxodonta Africana) Elephants and with a Discussion of Significance towards Fossilized Proboscidean Footprints. Quaternary International, 2017, 443:221-227.

[]	Paul G S. Wolberg D L, Stump E, Rosenberg G D. Dinosaur Models: The Good, the Bad, and Using Them to Estimate the Mass of Dinosaurs. DinoFest International Proceedings, 1997 New York The Academy of Natural Sciences 129-154.

[]	Qiu Z X, Wang B Y, Qiu Z D, et al. Land Mammal Geochronology and Magnetostratigraphy of Mid-Tertiary Deposits in the Lanzhou Basin, Gansu Province, China. Eclogae Geologicae Helvetiae, 2001, 94:373-385.

[]	Roger F, Tapponnier P, Arnaud N, et al. An Eocene Magmatic Belt across Central Tibet: Mantle Subduction Triggered by the Indian Collision?. Terra Nova, 2000, 12(3): 102-108.

[]	Roth V L. How Elephants Grow: Heterochrony and the Calibration of Developmental Stages in Some Living and Fossil Species. Journal of Vertebrate Paleontology, 1984, 4(1): 126-145.

[]	Roth V, Damuth J, MacFadden B. Insular Dwarf Elephants: A Case Study in Body Mass Estimation and Ecological Inference. Body Size in Mammalian Paleobiology: Estimation and Biological Implications, 1990 Cambridge Cambridge University Press 151-179.

[]	Rowley D B. Age of Initiation of Collision between India and Asia: A Review of Stratigraphic Data. Earth and Planetary Science Letters, 1996, 145(1/2/3/4): 1-13.

[]	Sarjeant W A, Langston W Jr. Vertebrate Footprints and Invertebrate Traces from the Cadronian (Late Eocene) of Trans-Pecos Texas. Texas Memorial Museum Bulletin, 1994, 36:1-86.

[]	Sarjeant W A, Wilson J. Late Eocene (Duchesnean) Mammal Footprints from the Skyline Channels of Trans-Pecos Texas. Texas Journal of Science, 1988, 40(4): 439-446.

[]	Sarjeant W A. The Study of Fossil Vertebrate Footprints. A Short History and Selective Bibliography. Glossary and Manual of Tetrapod Footprint Palaeoichnology, 1987, 1:1-19.

[]	Shipman P. Fox J W, Smith C B, Wilkins K T. Body Size and Broken Bones: Preliminary Interpretations of Proboscidean Remains. Proboscidean and Paleoindian Interactions, 1992 Waco Baylor University Press 75-98.

[]	Shoshani J. Understanding Proboscidean Evolution: A Formidable Task. Trends in Ecology & Evolution, 1998, 13(12): 480-487.

[]	Shoshani J, Tassy P. Shoshani J, Tassy P. Summary, Conclusions, and a Glimpse into the Future. The Proboscidea: Evolution and Palaeoecology of Elephants and Their Relatives, 1996 Oxford Oxford University Press 335-347.

[]	Shoshani J, West R M, Court N, et al. Shoshani J, Tassy P, et al. The Earliest Proboscideans: General Plan, Taxonomy, and Palaeoecology. The Proboscidea: Evolution and Palaeoecology of Elephants and Their Relatives, 1996 Oxford Oxford University Press 57-75.

[]	Sláma J, Košler J, Condon D J, et al. Plešovice Zircon—A New Natural Reference Material for U-Pb and Hf Isotopic Microanalysis. Chemical Geology, 2008, 249(1/2): 1-35.

[]	Spurlin M S, Yin A, Horton B K, et al. Structural Evolution of the Yushu-Nangqian Region and Its Relationship to Syncollisional Igneous Activity, East-Central Tibet. Geological Society of America Bulletin, 2005, 117(9): 1293

[]	Studnicki-Gizbert C, Burchfiel B C, Li Z, et al. Early Tertiary Gonjo Basin, Eastern Tibet: Sedimentary and Structural Record of the Early History of India-Asia Collision. Geosphere, 2008, 4(4): 713-735.

[]	Tang M Y, Jing L Z, Hoke G D, et al. Paleoelevation Reconstruction of the Paleocene – Eocene Gonjo Basin, SE-Central Tibet. Tectonophysics, 2017, 712/713:170-181.

[]	Tong Y B, Yang Z Y, Mao C P, et al. Paleomagnetism of Eocene Red-Beds in the Eastern Part of the Qiangtang Terrane and Its Implications for Uplift and Southward Crustal Extrusion in the Southeastern Edge of the Tibetan Plateau. Earth and Planetary Science Letters, 2017, 475:1-14.

[]	Vermeesch P. IsoplotR: A Free and Open Toolbox for Geochronology. Geoscience Frontiers, 2018, 9(5): 1479-1493.

[]	Wang C S, Zhao X X, Liu Z F, et al. Constraints on the Early Uplift History of the Tibetan Plateau. Proceedings of the National Academy of Sciences of the United States of America, 2008, 105(13): 4987-4992.

[]	Wang J H, Yin A, Harrison T M, et al. A Tectonic Model for Cenozoic Igneous Activities in the Eastern Indo-Asian Collision Zone. Earth and Planetary Science Letters, 2001, 188(1/2): 123-133.

[]	Wang L C, Yuan Q, Shen L J, et al. Middle Eocene Paleoenvironmental Reconstruction in the Gonjo Basin, Eastern Tibetan Plateau: Evidence from Palynological and Evaporite Records. Frontiers in Earth Science, 2022, 10:818418

[]	Western D, Moss C, Georgiadis N. Age Estimation and Population Age Structure of Elephants from Footprint Dimensions. The Journal of Wildlife Management, 1983, 47(4): 1192-1197.

[]	White L J T, Tutin C E G, Fernandez M. Group Composition and Diet of Forest Elephants, Loxodonta Africana Cyclotis Matschie 1900, in the Lopé Reserve, Gabon. African Journal of Ecology, 1993, 31(3): 181-199.

[]	Wiedenbeck M, Allé P, Corfu F, et al. Three Natural Zircon Standards for U-Th-Pb, Lu-Hf, Trace Element and Ree Analyses. Geostandards Newsletter, 1995, 19(1): 1-23.

[]	Wroblewski A F J, Gulas-Wroblewski B E. Earliest Evidence of Marine Habitat Use by Mammals. Scientific Reports, 2021, 11:8846

[]	Wu F Y, Ji W Q, Wang J G, et al. Zircon U-Pb and Hf Isotopic Constraints on the Onset Time of India-Asia Collision. American Journal of Science, 2014, 314(2): 548-579.

[]	Xia L Q, Li X M, Ma Z P, et al. Cenozoic Volcanism and Tectonic Evolution of the Tibetan Plateau. Gondwana Research, 2011, 19(4): 850-866.

[]	Xiao R, Zheng Y, Liu X, et al. Synchronous Sedimentation in Gonjo Basin, Southeast Tibet in Response to India-Asia Collision Constrained by Magnetostratigraphy. Geochemistry, Geophysics, Geosystems, 2021, 22(3): e2020GC009411

[]	Xing L D, Lockley M G, Falk A. First Record of Cenozoic Bird Footprints from East Asia (Tibet, China). Ichnos, 2013, 20(1): 19-23.

[]	Xiong Z Y, Ding L, Spicer R A, et al. The Early Eocene Rise of the Gonjo Basin, SE Tibet: From Low Desert to High Forest. Earth and Planetary Science Letters, 2020, 543:116312

[]	Yao T, Wu F Y, Ding L, et al. Multispherical Interactions and Their Effects on the Tibetan Plateau’s Earth System: A Review of the Recent Researches. National Science Review, 2015, 2:468-488.

[]	Yuan Q, Barbolini N, Ashworth L, et al. Palaeoenvironmental Changes in Eocene Tibetan Lake Systems Traced by Geochemistry, Sedimentology and Palynofacies. Journal of Asian Earth Sciences, 2021, 214:104778

[]	Zhang J J, Santosh M, Wang X X, et al. Tectonics of the Northern Himalaya since the India-Asia Collision. Gondwana Research, 2012, 21(4): 939-960.

[]	Zhang Y, Huang W T, Huang B C, et al. 53-43 Ma Deformation of Eastern Tibet Revealed by Three Stages of Tectonic Rotation in the Gongjue Basin. Journal of Geophysical Research: Solid Earth, 2018, 123(5): 3320-3338.

[]	Zhou J Y, Wang J H, An Y, et al. Sedimentology and Tectonic Significance of Paleogene Coarse Clastic Rocks in Eastern Tibet. Acta Geologica Sinica, 2003, 77(2): 262 271 296 (in Chinese with English Abstract)

[]	Zhou J Y, Wang J H, Horton B K, et al. The Closure of Paleogene Basins of East-Central Tibet in Response to Tectonic, Sedimentation, Magmatism and Paleoclimate. Acta Geologica Sinica, 2011, 85(2): 172 178 (in Chinese with English abstract)