青藏高原由海变陆的历史——构造与海平面双重奏

胡修棉; 马安林; 王建刚; 蒋璟鑫; 张世杰; 许艺炜; 赖文; 邓涛; 薛伟伟; 安慰; 王成善; 胡修棉; 马安林; 王建刚; 蒋璟鑫; 张世杰; 许艺炜; 赖文; 邓涛; 薛伟伟; 安慰; 王成善

doi:10.14027/j.issn.1000-0550.2025.046

[1]	Yin A, Harrison T M. Geologic evolution of the Himalayan-Tibetan orogen[J]. Annual Review of Earth and Planetary Sciences, 2000, 28: 211-280.
[2]	Molnar P, England P, Martinod J. Mantle dynamics, uplift of the Tibetan Plateau, and the Indian monsoon[J]. Reviews of Geophysics, 1993, 31(4): 357-396.
[3]	Spicer R A, Farnsworth A, Su T, et al. The progressive co-evolutionary development of the Pan-Tibetan Highlands, the Asian monsoon system and Asian biodiversity[J]. Geological Society, London, Special Publications, 2025, 549: 55-112.
[4]	章炳高，穆西南. 西藏雅鲁藏布江以北海相第三系的发现[J]. 地层学杂志，1979，3（1）：65-66. Zhang Binggao, Mu Xinan. Discovery of marine Tertiary north of the Yarlung Zangbo River, Tibet[J]. Journal of Stratigraphy, 1979, 3(1): 65-66.
[5]	郝诒纯，万晓樵. 西藏定日的海相白垩、第三系[J]. 青藏高原地质文集，1985（2）：227-232. Hao Yichun, Wan Xiaoqiao. The marine Cretaceous and Tertiary strata of Tingri, Xizang (Tibet)[J]. Contribution to the Geology of the Qinghai-Xizang (Tibet) Plateau, 1985(2): 227-232.
[6]	万晓樵. 西藏第三纪有孔虫生物地层及地理环境[J]. 现代地质，1987，1（1）：15-47. Wan Xiaoqiao. Foraminifera biostratigraphy and paleogeography of the Tertiary in Tibet[J]. Geoscience, 1987, 1(1): 15-47.
[7]	李祥辉，王成善，胡修棉，等. 朋曲组：西藏南部最高海相层位一个新的地层单元[J]. 地层学杂志，2000，24（3）：243-248. Li Xianghui, Wang Chengshan, Hu Xiumian, et al. The Pengqu Formation: A new Eocene stratigraphical unit in Tingri area, Tibet[J]. Journal of Stratigraphy, 2000, 24(3): 243-248.
[8]	李祥辉，吴铬，王成善，等. 西藏措勤盆地古生界—中生界岩相古地理演化[J]. 成都理工学院学报，2001，28（4）：331-339. Li Xianghui, Wu Ge, Wang Chengshan, et al. Paleozoic to Mesozoic changes of lithofacies and paleogeography of the Coqen Basin, central Tibet[J]. Journal of Chengdu University of Technology, 2001, 28(4): 331-339.
[9]	万晓樵，丁林，李建国，等. 西藏仲巴地区白垩纪末期—始新世早期海相地层[J]. 地层学杂志，2001，25（4）：267-272. Wan Xiaoqiao, Ding Lin, Li Jianguo, et al. Latest Cretaceous to Early Eocene marine strata in the Zhongba region, Tibet[J]. Journal of Stratigraphy, 2001, 25(4): 267-272.
[10]	李国彪，万晓樵，刘文灿，等. 藏南萨迦县赛区“混杂岩”放射虫的发现及其意义[J]. 地质通报，2003，22（11）：949-955. Li Guobiao, Wan Xiaoqiao, Liu Wencan, et al. Discovery of Cretaceous radiolarians in "mélanges" in Saiqu, Sa'gya, southern Tibet, and its geological significance[J]. Geological Bulletin of China, 2003, 22(11): 949-955.
[11]	李祥辉，张洁. 海平面及海平面变化综述[J]. 岩相古地理，1999，19（4）：61-72，41. Li Xianghui, Zhang Jie. A review of sea level and sea level changes[J]. Sedinentary Facica and Palaeogeography, 1999, 19(4): 61-72, 41.
[12]	王成善，李祥辉，万晓樵，等. 西藏南部江孜地区白垩系的厘定[J]. 地质学报，2000，74（2）：97-107. Wang Chengshan, Li Xianghui, Wan Xiaoqiao, et al. The Cretaceous in Gyangze, southern Xizang (Tibet): Redefined[J]. Acta Geologica Sinica, 2000, 74(2): 97-107.
[13]	Wang C S, Li X H, Hu X M, et al. Latest marine horizon north of Qomolangma (Mt Everest): Implications for closure of tethys seaway and collision tectonics[J]. Terra Nova, 2002, 14(2): 114-120.
[14]	尹集祥，孙晓兴，孙亦因，等. 西藏南部日喀则地区双磨拉石带磨拉石岩系的地层学研究[J]. 国科学院地质研究所集刊，1988，3：159-176. Yin Jixiang, Sun Xiaoxing, Sun Yiyin, et al. Stratigraphic study of the Shuangmoluo Formation in the Rikaze area, southern Tibet[J]. Journal of the Institute of Geology, Chinese Academy of Sciences, 1988, 3: 159-176.
[15]	刘成杰，尹集详，孙晓兴，等. 西藏南部日喀则弧前盆地非复理石型海相上白垩统—下第三系[J]. 中国科学院地质研究所集刊，1988(3)：130-157. Liu Chengjie, Yin Jixiang, Sun Xiao-xing, et al. The non-turbidite marine Upper Cretaceous-Lower Tertiary in the Rikaze forearc basin, southern Tibet[J]. Journal of the Institute of Geology, Chinese Academy of Sciences, 1988(3): 130-157.
[16]	万晓樵，丁林. 西藏吉隆白垩纪末期浮游有孔虫的发现及其年代意义[J]. 古生物学报，2002，41（1）：89-95. Wan Xiaoqiao, Ding Lin. Discovery of the latest Cretaceous planktonic foraminifera from Gyirong of southern Tibet and its chronostratigraphic significance[J]. Acta Palaeontologica Sinica, 2002, 41(1): 89-95.
[17]	章炳高. 西藏的圆笠虫（OrbitoLina）动物群[M]. 青藏高原科学考察丛书，西藏古生物（第四分册）. 北京：科学出版社，1982. Zhang Binggao. The OrbitoLina fauna in Tibet[M]. Scientific expedition to the Qinghai-Tibet Plateau, Tibetan paleobiology (Volume 4). Beijing: Science Press, 1982.
[18]	章炳高. 申扎、班戈早白垩世圆笠虫[J]. 中国科学院南京地质古生物学研究所丛刊，1986（10）：101-122. Zhang Binggao. Early Cretaceous OrbitoLina from Shenzha and Bangor[J]. Bulletin of the Nanjing Institute of Geology and Palaeontology, Chinese Academy of Sciences, 1986(10): 101-122.
[19]	杨遵仪，聂泽同，吴顺宝，等. 西藏阿里地区白垩纪固着蛤类及其地质意义[J]. 地质学报，1982（4）：293-300. Yang Zunyi, Nie Zetong, Wu Shunbao, et al. Cretaceous rudists from Ngari, Xizang (Tibet), autonomous region, China and their geologic significance[J]. Acta Geologica Sinica, 1982(4): 293-300.
[20]	苟宗海. 西藏革吉地区白垩纪的固着蛤类（RUDISTS）化石[J]. 西藏地质，1994（1）：128-138. Gou Zonghai. The Cretaceous rudist fossils in Geji area of Tibet[J]. Tibet Geology, 1994(1): 128-138.
[21]	Scott R W, Wan X Q, Sha J G, et al. Rudists of Tibet and the Tarim Basin, China: Significance to Requieniidae phylogeny[J]. Journal of Paleontology, 2010, 84(3): 444-465.
[22]	Rao X, Skelton P W, Sha J G, et al. Mid-Cretaceous rudists (Bivalvia: Hippuritida) from the Langshan Formation, Lhasa Block, Tibet[J]. Papers in Palaeontology, 2015, 1(4): 401-424.
[23]	余光明，王成善. 西藏特提斯沉积地质[M]. 北京：地质出版社，1990. Yu Guangming, Wang Chengshan. Sedimentary ge-ology of the tethys in Tibet[M]. Beijing: Geological Publishing House, 1990.
[24]	陈明，王剑，谭富文，等. 措勤盆地下白垩统郎山组生物礁的平面分布特征及意义探讨[J]. 沉积与特提斯地质，2003，23（4）：68-70. Chen Ming, Wang Jian, Tan Fuwen, et al. The planar distribution and significance of the organic reefs in the Lower Cretaceous Langshan Formation in the Coqen Basin, Xizang[J]. Sedimentary Geology and Tethyan Geology, 2003, 23(4): 68-70.
[25]	李祥辉，曾庆高，吴铬，等. 西藏措勤盆地北部下白垩统层序地层特征[J]. 成都理工大学学报（自然科学版），2005，32（2）：111-119. Li Xianghui, Zeng Qinggao, Wu Ge, et al. Lower Cretaceous sequence stratigraphy of northern Coqen Basin, central Tibet, China[J]. Journal of Chengdu University of Technology (Science Technology Edition), 2005, 32(2): 111-119.
[26]	万晓樵，吴雁华，李国彪. 西藏白垩纪中期Orbitolinids（有孔虫）的分布与古地理意义[J]. 地质学报，2003，77（1）：1-8. Wan Xiaoqiao, Wu Yanhua, Li Guobiao. Distribution of mid-Cretaceous Orbitolinids in Xizang (Tibet) and its paleobiogeographic implications[J]. Acta Geologica Sinica, 2003, 77(1): 1-8.
[27]	Fu X G, Wang J, Qu W J, et al. Re-Os (ICP-MS) dating of marine oil shale in the Qiangtang Basin, northern Tibet, China[J]. Oil Shale, 2008, 25(1): 47-55.
[28]	戴霜，张明震，彭栋祥，等. 中国西北地区中—新生代构造与气候格局演化[J]. 海洋地质与第四纪地质，2013，33（4）：153-168. Dai Shuang, Zhang Mingzhen, Peng Dongxiang, et al. The Mesozoic-Cenozoic evolution of the tectonic and climatic patterns, NW China evolution of Meso-Cenozoic tectonic and climatic patterns in Northwest China[J]. Marine Geology and Quaternary Geology, 2013, 33(4): 153-168.
[29]	潘桂棠，丁俊，姚冬生，等. 1：150万青藏高原及邻区1:150万地质图及说明书[M]. 成都：成都地图出版社，2004. Pan Guitang, Ding Jun, Yao Dongsheng, et al. Geological map of the Qinghai-Tibet Plateau and adjacent areas, 1: 1500000[M]. Chengdu: Chengdu Map Publishing House, 2004.
[30]	朱迎堂，郭通珍，张雪亭，等. 青海西部可可西里湖地区晚三叠世诺利期地层的厘定及其意义[J]. 地质通报，2003，22（7）：474-479. Zhu Yingtang, Guo Tongzhen, Zhang Xueting, et al. Discovery of Triassic Norian strata in the Hoh Xil Lake area, western Qinghai, and its geological significance[J]. Geological Bulletin of China, 2003, 22(7): 474-479.
[31]	贾宝华，孟德保，柏道远，等. 中华人民共和国区域地质调查报告，比例尺：1：250000，银石山幅（J45C004002），比例尺1:250000[R]. 2003. Jia Baohua, Meng Debao, Bai Daoyuan, et al. Regional geological survey report of the People's Republic of China, scale: 1:250000, Yingshi Mountain Sheet (J45C004002)[R]. 2003.
[32]	Ma A L, Hu X M, Kapp P, et al. The disappearance of a Late Jurassic remnant sea in the southern Qiangtang Block (Shamuluo Formation, Najiangco area): Implications for the tectonic uplift of central Tibet[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 2018, 506: 30-47.
[33]	Ma A L, Hu X M, Garzanti E, et al. Diachronous Cretaceous closure of the Bangong-Nujiang-Shyok Ocean (westernmost central Tibet)[J]. Tectonics, 2024, 43(12): e2024TC008280.
[34]	Kapp P, DeCelles P G, Gehrels G E, et al. Geological records of the Lhasa-Qiangtang and Indo-Asian collisions in the Nima area of central Tibet[J]. Geological Society of America Bulletin, 2007, 119(7/8): 917-933.
[35]	Fan J J, Niu Y L, Liu Y M, et al. Timing of closure of the Meso-Tethys Ocean: Constraints from remnants of a 141-135 Ma ocean island within the Bangong–Nujiang Suture Zone, Tibetan Plateau[J]. GSA Bulletin, 2021, 133(9/10): 1875-1889.
[36]	Hu X M, Wang J G, BouDagher-Fadel M, et al. New insights into the timing of the India–Asia collision from the Paleogene Quxia and Jialazi formations of the Xigaze Forearc Basin, South Tibet[J]. Gondwana Research, 2016, 32: 76-92.
[37]	Jiang J X, Hu X M, Li J, et al. Discovery of the Paleocene-Eocene Thermal Maximum in shallow-marine sediments of the Xigaze Forearc Basin, Tibet: A record of enhanced extreme precipitation and siliciclastic sediment flux[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 2021, 562: 110095.
[38]	Orme D A, Carrapa B, Kapp P. Sedimentology, provenance and geochronology of the Upper Cretaceous–Lower Eocene western Xigaze Forearc Basin, southern Tibet[J]. Basin Research, 2015, 27(4): 387-411.
[39]	孙高远，王建刚，胡修棉，等. 西藏札达地区上白垩统—下始新统达机翁组：对冈底斯弧前盆地演化的制约[J]. 岩石学报，2018，34（6）：1847-1861. Sun Gaoyuan, Wang Jiangang, Hu Xiumian, et al. Upper Cretaceous-Lower Eocene Dajiweng Formation in the Zhada area, southern Tibet: Implications for the Trans-Himalayan forearc baisn evolution[J]. Acta Petrologica Sinica, 2018, 34(6): 1847-1861.
[40]	Wang J G, Hu X M, BouDagher-Fadel M, et al. Early Eocene sedimentary recycling in the Kailas area, southwestern Tibet: Implications for the initial India–Asia collision[J]. Sedimentary Geology, 2015, 315: 1-13.
[41]	胡修棉，李娟，安慰，等. 藏南白垩纪—古近纪岩石地层厘定与构造地层划分[J]. 地学前缘，2017，24（1）：174-194. Hu Xiumian, Li Juan, An Wei, et al. The redefinition of Cretaceous-Paleogene lithostratigraphic units and tectonostratigraphic division in southern Tibet[J]. Earth Science Frontiers, 2017, 24(1): 174-194.
[42]	Jiang T, Aitchison J C, Wan X Q. The youngest marine deposits preserved in southern Tibet and disappearance of the Tethyan Ocean[J]. Gondwana Research, 2016, 32: 64-75.
[43]	Zhang Q, Zhang Q H, Ding L, et al. Seawater retreated from the Tethyan Himalaya of south Tibet at ca. 49 Ma, not ca. 34 Ma[J]. Geological Society of America Bulletin, 2025, 137(5/6): 1995-2015.
[44]	朱迎堂，李建星，伊海生，等. 青藏高原东部玉树隆宝蛇绿混杂岩中早二叠世放射虫的发现及其地质意义[J]. 成都理工大学学报（自然科学版），2006，33（5）：485-490. Zhu Yingtang, Li Jianxing, Yi Haisheng, et al. Early Permian radiolarians from the Longbao ophiolitic mélange in Yushu area, Qinghai-Tibet Plateau, China[J]. Journal of Chengdu University of Technology (Science Technology Edition), 2006, 33(5): 485-490.
[45]	张发德，岳天祥，宋令莉. 通天河上游墩日含煤岩系地层时代的新认识[J]. 青海地质，1998（2）：6-10. Zhang Fade, Yue Tianxiang, Song Lingli. New recognition on the stratigraphic age of Dunri coal-bearing rock series in the upper reaches of Tongtian River[J]. Qinghai Geology, 1998(2): 6-10.
[46]	辜学达，刘啸虎. 四川省岩石地层[M]. 武汉：中国地质大学出版社，1997. Gu Xueda, Liu Xiaohu. Stratigraphy (lithostratic) of Sichuan province[M]. Wuhan: China University of Geo-sciences Press, 1997.
[47]	邓文诗，张丽霞，成永盛. 青海省下中侏罗统含煤岩系沉积特征及聚煤作用[J]. 中国煤炭地质，2009，21（增刊2）：14-18，56. Deng Wenshi, Zhang Lixia, Cheng Yongsheng. Coal-bearing strata sedimentary features and coal accumulation process in lower middle series, Jurassic System, Qinghai province[J]. Coal Geology of China, 2009, 21(Suppl.2): 14-18, 56.
[48]	李聪聪，孙顺新，乔军伟，等. 青藏高原北部煤系特征及煤系矿产研究方向初探[J]. 中国煤炭地质，2015，27（5）：1-5，11. Li Congcong, Sun Shunxin, Qiao Junwei, et al. Coal measures features and mineral resources research orientation in northern Qinghai-Tibetan Plateau[J]. Coal Geology of China, 2015, 27(5): 1-5, 11.
[49]	乔军伟. 青藏高原聚煤作用[D]. 徐州：中国矿业大学，2019. Qiao Junwei. Coal accumulation in the Qinghai-Tibet Plateau[D]. Xuzhou: China University of Mining and Technology, 2019.
[50]	严松涛，朱利东，吴青松，等. 四川新龙地区甘孜—理塘蛇绿混杂岩带侏罗系地层沉积学、地球化学和年代学研究及其构造背景分析[J]. 岩石学报，2022，38（4）：1149-1168. Yan Songtao, Zhu Lidong, Wu Qingsong, et al. Sedimentology, geoche-mistry and chronology of Jurassic in the Ganzi-Litang ophiolite mélange belt of Xinlong area, Sichuan and its tectonic setting[J]. Acta Petrologica Sinica, 2022, 38(4): 1149-1168.
[51]	Jackson Jr W T, Robinson D M, Weislogel A L, et al. Cenozoic development of the nonmarine Mula Basin in the southern Yidun terrane: Deposition and deformation in the eastern Tibetan Plateau associated with the India-Asia collision[J]. Tectonics, 2018, 37(8): 2446-2465.
[52]	Jackson Jr W T, Robinson D M, Weislogel A L, et al. Mesozoic development of nonmarine basins in the northern Yidun terrane: Deposition and deformation in the eastern Tibetan Plateau prior to the India-Asia collision[J]. Tectonics, 2018, 37(8): 2466-2485.
[53]	Ma A L, Hu X M, Garzanti E, et al. Sedimentary and tectonic evolution of the southern Qiangtang Basin: Implications for the Lhasa-Qiangtang collision timing[J]. Journal of Geophysical Research: Solid Earth, 2017, 122(7): 4790-4813.
[54]	Ma A L, Hu X M, Garzanti E, et al. Paleogeographic and tectonic evolution of Mesozoic Qiangtang basins (Tibet)[J]. Tectonophysics, 2023, 862: 229957.
[55]	Xue W W, Hu X M, Ma A L, et al. Eustatic and tectonic control on the evolution of the Jurassic North Qiangtang Basin, northern Tibet, China: Impact on the petroleum system[J]. Marine and Petroleum Geology, 2020, 120: 104558.
[56]	Meng J, Zhao X X, Wang C S, et al. Palaeomagnetism and detrital zircon U–Pb geochronology of Cretaceous redbeds from central Tibet and tectonic implications[J]. Geological Journal, 2018, 53(5): 2315-2333.
[57]	Ma A L, Hu X M, Garzanti E, et al. Mid-Cretaceous exhumation of the central Qiangtang Mountain range metamorphic rocks as evidenced by the Abushan continental redbeds[J]. Tectonics, 2023, 42(3): e2022TC007520.
[58]	Ma A L, Hu X M, Garzanti E, et al. Discovery of ≥ 105 Ma continental redbeds in the Qiangtang Block: Implications for the early uplift of central Tibet[J]. Mesozoic, 2024, 1(3): 340-348.
[59]	Xu Y W, Hu X M, Garzanti E, et al. Mid-Cretaceous thick carbonate accumulation in northern Lhasa (Tibet): Eustatic vs. tectonic control?[J]. GSA Bulletin, 2022, 134(1/2): 389-404.
[60]	Lai W, Hu X M, Garzanti E, et al. Early Cretaceous sedimentary evolution of the northern Lhasa terrane and the timing of initial Lhasa-Qiangtang collision[J]. Gondwana Research, 2019, 73: 136-152.
[61]	BouDagher-Fadel M K, Hu X M, Price G D, et al. Foraminiferal biostratigraphy and palaeoenvironmental analysis of the Mid-Cretaceous limestones in the southern Tibetan Plateau[J]. Journal of Foraminiferal Research, 2017, 47(2): 188-207.
[62]	Sun G Y, Hu X M, Sinclair H D. Early Cretaceous palaeogeographic evolution of the Coqen Basin in the Lhasa Terrane, southern Tibetan Plateau[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 2017, 485: 101-118.
[63]	Xu Y W, Hu X M, BouDagher-Fadel M K, et al. The major Late Albian transgressive event recorded in the epeiric platform of the Langshan Formation in central Tibet[J]. Geological Society, London, Special Publications, 2020, 498(1): 211-232.
[64]	叶加鹏，胡修棉，孙高远，等. 革吉最高海相层约束班怒残留海消亡时间（~94 Ma）[J]. 科学通报，2019，64（15）：1620-1636. Ye Jiapeng, Hu Xiumian, Sun Gaoyuan, et al. The disappearance of the Late Cretaceous Bangong-Nujiang residual seaway constrained by youngest marine strata in Geji area, Lhasa Terrane[J]. Chinese Science Bulletin, 2019, 64(15): 1620-1636.
[65]	Wang J G, Hu X M, Garzanti E, et al. From extension to tectonic inversion: Mid-Cretaceous onset of Andean-type orogeny in the Lhasa Block and early topographic growth of Tibet[J]. GSA Bulletin, 2020, 132(11/12): 2432-2454.
[66]	Sun G Y, Hu X M, Sinclair H D, et al. Late Cretaceous evolution of the Coqen Basin (Lhasa terrane) and implications for early topographic growth on the Tibetan Plateau[J]. GSA Bulletin, 2015, 127(7/8): 1001-1020.
[67]	孙高远，胡修棉. 拉萨地体中部上白垩统达雄组的建立及构造隆升意义[J]. 地质学报，2017，91（12）：2623-2637. Sun Gaoyuan, Hu Xiumian. The establishment of the Upper Cretaceous Daxiong Formation in the central Lhasa Terrane and its implications for tectonic uplifting[J]. Acta Geologica Sinica, 2017, 91(12): 2623-2637.
[68]	Lai W, Hu X M, Garzanti E, et al. Initial growth of the northern Lhasaplano, Tibetan Plateau in the early Late Cretaceous (ca. 92 Ma)[J]. GSA Bulletin, 2019, 131(11/12): 1823-1836.
[69]	Gao B, Chen J T, Qie W, et al. Revisiting the paleogeographic framework of northeastern Gondwana in the Late Paleozoic: Implications from detrital zircon analysis[J]. Sedimentary Geology, 2022, 434: 106144.
[70]	Bosboom R, Dupont-Nivet G, Grothe A, et al. Timing, cause and impact of the Late Eocene stepwise sea retreat from the Tarim Basin (west China)[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 2014, 403: 101-118.
[71]	Sun J M, Sha J G, Windley B F, et al. Late Eocene stepwise seawater retreat from the Pamir-Tian Shan convergence zone (Alay Valley) in the western Tarim Basin, China[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 2023, 622: 111603.
[72]	Bosboom R, Dupont-Nivet G, Grothe A, et al. Linking Tarim Basin sea retreat (west China) and Asian aridification in the Late Eocene[J]. Basin Research, 2014, 26(5): 621-640.
[73]	Sun J M, Windley B F, Zhang Z L, et al. Diachronous seawater retreat from the southwestern margin of the Tarim Basin in the Late Eocene[J]. Journal of Asian Earth Sciences, 2016, 116: 222-231.
[74]	周志毅. 塔里木盆地各纪地层[M]. 北京：科学出版社，2001. Zhou Zhiyi. Stratigraphy of the Tarim Basin[M]. Beijing: Science Press, 2001.
[75]	Nicora A, Garzanti E, Fois E. Evolution of the Tethys Himalaya continental shelf during Maastrichtian to Paleocene (Zanskar, India)[J]. Rivista Italiana di Paleontologia e Stratigrafia, 1987, 92(4): 439-496.
[76]	Green O R, Searle M P, Corfield R I, et al. Cretaceous-Tertiary carbonate platform evolution and the age of the India-Asia collision along the Ladakh Himalaya (Northwest India)[J]. The Journal of Geology, 2008, 116(4): 331-353.
[77]	DeCelles P G, Gehrels G E, Quade J, et al. Eocene-Early Miocene foreland basin development and the history of Himalayan thrusting, western and central Nepal[J]. Tectonics, 1998, 17(5): 741-765.
[78]	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[J]. Earth and Planetary Science Letters, 2004, 227(3/4): 313-330.
[79]	Najman Y, Carter A, Oliver G, et al. Provenance of Eocene foreland basin sediments, Nepal: Constraints to the timing and diachroneity of Early Himalayan orogenesis[J]. Geology, 2005, 33(4): 309-312.
[80]	Vermeesch P. Maximum depositional age estimation revisited[J]. Geoscience Frontiers, 2021, 12(2): 843-850.
[81]	Hurtig N C, Georgiev S V, Stein H J, et al. Re-Os systematics in petroleum during water-oil interaction: The effects of oil chemistry[J]. Geochimica et Cosmochimica Acta, 2019, 247: 142-161.
[82]	Sun Y Y, Liang Y, Liu H, et al. Mid-Miocene sea level altitude of the Qaidam Basin, northern Tibetan Plateau[J]. Communications Earth Environment, 2023, 4(1): 3.
[83]	赵仁夫，朱迎堂，周庆华，等. 青海玉树地区三叠纪地层之下角度不整合面的发现及意义[J]. 地质通报，2004，23（5/6）：616-619. Zhao Renfu, Zhu Yingtang, Zhou Qinghua, et al. Discovery of angular unconformity below Triassic strata in the Yushu area, Qinghai[J]. Geological Bulletin of China, 2004, 23(5/6): 616-619.
[84]	Cao Y, Xu Q, Tan X C, et al. Regional unconformities dating closure of the Paleo-Tethys Ocean in the Late Anisian (Middle Triassic)[J]. Geological Society of America Bulletin, 2025, 137(7/8): 3495-3511.
[85]	Ma A L, Hu X M, Kapp P, et al. Pre-Oxfordian (163 Ma) ophiolite obduction in central Tibet[J]. Geophysical Research Letters, 2020, 47(10): e2019GL086650.
[86]	Ma A L, Hu X M, Chew D, et al. A latest Jurassic to Early Cretaceous syn-collisional trench sequence in central Tibet recorded the role of microcontinents in Lhasa–Qiangtang collision[J]. Tectonics, 2025, 44(3): e2024TC008535.
[87]	Lai W, Hu X M, Ma A L, et al. From the southern Gangdese Yeba arc to the Bangong-Nujiang Ocean: Provenance of the Upper Jurassic-Lower Cretaceous Lagongtang Formation (northern Lhasa, Tibet)[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 2022, 588: 110837.
[88]	朱志才, 翟庆国, 胡培远, 等. 拉萨—羌塘地体碰撞时限: 来自班公湖—怒江缝合带中段多尼组沉积的约束[J]. 沉积学报, 2020, 38(4): 712-726. Zhu Zhicai, Zhai Qingguo, Hu Peiyuan, et al. Timing of the Lhasa-Qiangtang collision: Constraints from the sedimentary records of the Duoni Formation from the middle segment of the Bangong-Nujiang suture zone[J]. Acta Sedimentologica Sinica, 2020, 38(4): 712-726
[89]	Hu Y L, Liu Z B, Wang G H, et al. Study of molasse within the middle segment of the Bangong-Nujiang suture zone, central Tibet: Constraints of ocean–continent transform[J]. Geological Journal, 2020, 55(10): 6625-6641.
[90]	潘桂棠，郑海翔，徐耀荣，等. 初论班公湖—怒江结合带[J]. 青藏高原地质文集，1983（4）：229-242. Pan Guitang, Zheng Haixiang, Xu Yaorong, et al. Priliminary study on Bangong Co-Nujiang Suture[J]. Collection of Qinghai-Tibet Plateau Geology, 1983(4): 229-242.
[91]	Hu X M, Garzanti E, Wang J G, et al. The timing of India-Asia collision onset–Facts, theories, controversies[J]. Earth-Science Reviews, 2016, 160: 264-299.
[92]	闫臻，方爱民，潘裕生，等. 西藏达金砾岩沉积环境、有孔虫时代及其大地构造意义[J]. 自然科学进展，2005，15（5）：565-571. Yan Zhen, Fang Aimin, Pan Yusheng, et al. Depositional environment of the Dajin conglomerate in Tibet, foraminiferal age, and its tectonic significance[J]. Progress in Natural Science, 2005, 15(5): 565-571.
[93]	李顺，丁林，付佳俊，等. 西藏达金砾岩的沉积时代、物源及构造背景[J]. 岩石学报，2016，32（11）：3537-3546. Li Shun, Ding Lin, Fu Jiajun, et al. Age, provenance and tectonic setting of Dajin conglomerate, Tibet[J]. Acta Petrologica Sinica, 2016, 32(11): 3537-3546.
[94]	Henderson A L, Foster G L, Najman Y. Testing the application of in situ Sm–Nd isotopic analysis on detrital apatites: A provenance tool for constraining the timing of India–Eurasia collision[J]. Earth and Planetary Science Letters, 2010, 297(1/2): 42-49.
[95]	Ding L, Kapp P, Wan X Q. Paleocene–Eocene record of ophiolite obduction and initial India-Asia collision, south central Tibet[J]. Tectonics, 2005, 24(3): TC3001.
[96]	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[J]. Tectonics, 2014, 33(5): 824-849.
[97]	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)[J]. Geology, 2015, 43(10): 859-862.
[98]	An W, Hu X M, Garzanti E, et al. New precise dating of the India-Asia collision in the Tibetan Himalaya at 61 Ma[J]. Geophysical Research Letters, 2021, 48(3): e2020GL090641.
[99]	Zhu B, Kidd W S F, Rowley D B, et al. Age of initiation of the India-Asia collision in the east-central Himalaya[J]. The Journal of Geology, 2005, 113(3): 265-285.
[100]	Najman Y, Appel E, Boudagher-Fadel M, et al. Timing of India-Asia collision: Geological, biostratigraphic, and palaeomagnetic constraints[J]. Journal of Geophysical Research: Solid Earth, 2010, 115(B12): B12416.
[101]	Hu X M, Sinclair H D, Wang J G, et al. Late Cretaceous-Palaeogene stratigraphic and basin evolution in the Zhepure Mountain of southern Tibet: Implications for the timing of India-Asia initial collision[J]. Basin Research, 2012, 24(5): 520-543.
[102]	Zhang Q H, Willems H, Ding L, et al. Initial India-Asia continental collision and foreland basin evolution in the Tethyan Himalaya of Tibet: Evidence from stratigraphy and paleontology[J]. The Journal of Geology, 2012, 120(2): 175-189.
[103]	Hoshina K, Wang Y S, Jiang S J, et al. Eocene calcareous nannofossils from southern Tibet: Paleoceanographic implications for the closure of the eastern Tethys Ocean[J]. Marine Micro-paleontology, 2021, 167: 102031.
[104]	Garzanti E, Baud A, Mascle G. Sedimentary record of the northward flight of India and its collision with Eurasia (Ladakh Himalaya, India)[J]. Geodinamica Acta, 1987, 1(4/5): 297-312.
[105]	陶君容. 西藏拉孜县柳区组植物化石组合及古气候意义[J]. 中国科学院地质研究所集刊，1988，3：223-238. Tao Junrong. Plant fossil assemblages of the Liuqu Formation in Lazha county, Tibet and their paleoclimatic significance[J]. Journal of the Institute of Geology, Chinese Academy of Sciences, 1988, 3: 223-238.
[106]	方爱民，闫臻，刘小汉，等. 藏南柳区砾岩中古植物化石群的时代及其在大地构造上的意义[J]. 自然科学进展，2004，14（12）：1419-1427. Fang Aimin, Yan Zhen, Liu Xiaohan, et al. The age of the paleobotanical fossil group in the Liubu conglomerate of southern Tibet and its tectonic significance[J]. Progress in Natural Science, 2004, 14(12): 1419-1427.
[107]	韦利杰，刘小汉，严富华，等. 藏南古近系柳区砾岩孢粉化石的发现及初步研究[J]. 微体古生物学报，2009，26（3）：249-260. Wei Lijie, Liu Xiaohan, Yan Fuhua, et al. Discovery and preliminary study on palynofossils from the Paleogene Liuqu conglomerates in southern Xizang (Tibet)[J]. Acta Micropalaeontologica Sinica, 2009, 26(3): 249-260.
[108]	Li G W, Kohn B, Sandiford M, et al. Constraining the age of Liuqu conglomerate, southern Tibet: Implications for evolution of the India–Asia collision zone[J]. Earth and Planetary Science Letters, 2015, 426: 259-266.
[109]	Leary R J, DeCelles P G, Quade J, et al. The Liuqu conglomerate, southern Tibet: Early Miocene basin development related to deformation within the Great Counter Thrust system[J]. Lithosphere, 2016, 8(5): 427-450.
[110]	Weislogel A L, Graham S A, Chang E Z, et al. Detrital zircon provenance from three turbidite depocenters of the Middle-Upper Triassic Songpan-Ganzi complex, central China: Record of collisional tectonics, erosional exhumation, and sediment production[J]. GSA Bulletin, 2010, 122(11/12): 2041-2062.
[111]	王康明，龙斌，李雁龙，等. 四川木里海相侏罗纪地层的发现及地质意义[J]. 地质通报，2002，21（7）：421-427. Wang Kangming, Long Bin, Li Yanlong, et al. Discovery of marine Jurassic strata at Muli, Sichuan, and its geological implications[J]. Geological Bulletin of China, 2002, 21(7): 421-427.
[112]	王全伟，戴宗明，阚泽忠，等. 川西甘孜—理塘构造带侏罗纪海相地层的特征[J]. 地质通报，2009，28（7）：907-914. Wang Quanwei, Dai Zongming, Kan Zezhong, et al. Marine Jurassic strata of Graze-Litang structural belt in western Sichuan, China[J]. Geological Bulletin of China, 2009, 28(7): 907-914.
[113]	王全伟，王康明，阚泽忠，等. 川西甘孜—理塘构造带侏罗纪地层特征及其与邻区的对比[J]. 沉积与特提斯地质，2009，29（2）：86-92. Wang Quanwei, Wang Kangming, Kan Zezhong, et al. Division and correlation of the Jurassic strata in the Garze-Litang structural zone, western Sichuan and its adjacent areas[J]. Sedimentary Geology and Tethyan Geology, 2009, 29(2): 86-92.
[114]	宁括步，毛世东，梁龙飞，等. 川西甘孜－理塘结合带碳酸盐岩碳氧同位素特征[J]. 沉积与特提斯地质，2018，38（3）：106-112. Ning Kuobu, Mao Shidong, Liang Longfei, et al. Carbon and oxygen isotopic analysis of the carbonate rocks in the Garze-Litang suture zone, western Sichuan[J]. Sedimentary Geology and Tethyan Geology, 2018, 38(3): 106-112.
[115]	刘祥，詹琼窑，朱弟成，等. 松潘—甘孜褶皱带南部上三叠统物源及构造抬升：碎屑锆石年代学和Hf同位素证据[J]. 岩石学报，2021，37（11）：3513-3538. Liu Xiang, Zhan Qiongyao, Zhu Dicheng, et al. Provenance and tectonic uplift of the Upper Triassic strata in the southern Songpan-Ganzi fold belt, SW China: Evidence from detrital zircon geochronology and Hf isotope[J]. Acta Petrologica Sinica, 2021, 37(11): 3513-3538.
[116]	Ding L, Yang D, Cai F L, et al. Provenance analysis of the Mesozoic Hoh-Xil-Songpan-Ganzi turbidites in northern Tibet: Implications for the tectonic evolution of the eastern Paleo-Tethys Ocean[J]. Tectonics, 2013, 32(1): 34-48.
[117]	李建国，饶馨，牟林，等. 青藏高原及其周边侏罗纪综合地层、生物群与古地理演化[J]. 中国科学：地球科学，2024，54（4）：1211-1243. Li Jianguo, Rao Xin, Mou Lin, et al. Jurassic integrative stratigraphy, biotas, and paleogeographical evolution of the Qinghai-Tibetan Plateau and its surrounding areas[J]. Science China Earth Sciences, 2024, 54(4): 1211-1243.
[118]	He S L, Ding L, Xiong Z Y, et al. A distinctive Eocene Asian monsoon and modern biodiversity resulted from the rise of eastern Tibet[J]. Science Bulletin, 2022, 67(21): 2245-2258.
[119]	薛伟伟, 马安林, 胡修棉. 羌塘盆地侏罗系—白垩系岩石地层格架厘定[J]. 地质论评, 2020, 66(5): 1114-1129. Xue Weiwei, Ma Anlin, Hu Xiumian. The redefinition of the Jurassic-Cretaceous lithostratigraphic framework in the Qiangtang Basin, Xizang Plateau[J]. Geological Review, 2020, 66: 1114-1129.
[120]	Fang X M, Song C H, Yan M D, et al. Mesozoic litho-and magneto-stratigraphic evidence from the central Tibetan Plateau for megamonsoon evolution and potential evaporites[J]. Gondwana Research, 2016, 37: 110-129.
[121]	Xu Y W, Lai W, Hu X M. Palaeoenvironmental analysis of the Langshan Formation in the Xiongba area[J]. Mesozoic, 2024, 1(3): 379-388.
[122]	Han X, Dai J G, Lin J, et al. The Middle Cretaceous (110-94 Ma) evolution of Tangza Basin in the western Tibetan Plateau and implications for initial topographic growth of northern Lhasa[J]. GSA Bulletin, 2021, 133(5/6): 1283-1300.
[123]	新疆维吾尔自治区区域地层表编写组. 西北地区区域地层表：新疆维吾尔自治区分册[M]. 北京：地质出版社，1981. Compiling Group for Xinjiang Regional Stratigraphic Chart. Regional stratigraphic chart of northwestern China, branch of Xinjiang Uygur Autonomous Region[M]. Beijing: Geological Publishing House, 1981.
[124]	Burtman V S, Molnar P. Geological and geophysical evidence for deep subduction of continental crust beneath the Pamir[J]. Geological Society of America Special Paper 281, 1993: 1-76.
[125]	文世宣，孙东立，尹集祥，等. 第二章：地层. 潘裕生，文世宣，孙东立. 喀喇昆仑山—昆仑山地区地质演化[M]. 北京：科学出版社，2000. Wen Shixuan, Sun Dongli, Yin Jixiang, et al. Chapter 2: Stratigraphy. Pan Yusheng, Wen Shixuan, Sun Dongli. Geological evolution of the Karakoram-Kunlun region[M]. Beijing: Science Press, 2000.
[126]	Zhang S J, Hu X M, Garzanti E. Paleocene initial indentation and early growth of the Pamir as recorded in the western Tarim Basin[J]. Tectonophysics, 2019, 772: 228207.
[127]	Gao B T, Zhang Q H, Ding L, et al. Age of the latest marine sedimentation in the western Kunlun area constrained by planktic foraminifera[J]. Palaeoworld, 2023, 32(3): 490-508.
[128]	唐天福，杨恒仁，兰琇，等. 新疆塔里木盆地西部白垩纪至早第三纪海相地层及含油性[M]. 北京：科学出版社，1989. Tang Tianfu, Yang Hengren, Lan Xiu, et al. Cretaceous to Early Tertiary marine strata and oil-bearing properties in the western Tarim Basin, Xinjiang[M]. Beijing: Science Press, 1989.
[129]	唐天福，薛耀松，俞从流，等. 新疆塔里木盆地西部晚白垩世至早第三纪海相沉积特征及沉积环境[M]. 北京：科学出版社，1992. Tang Tianfu, Xue Yaosong, Yu Congliu, et al. Marine sedimentary characteristics and sedimentary environment from Late Cretaceous to Early Tertiary in the western Tarim Basin, Xinjiang[M]. Beijing: Science Press, 1992.
[130]	Zhang S J, Hu X M, Han Z, et al. Climatic and tectonic controls on Cretaceous-Palaeogene sea-level changes recorded in the Tarim epicontinental sea[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 2018, 501: 92-110.
[131]	Kaya M Y, Dupont-Nivet G, Proust J N, et al. Paleogene evolution and demise of the proto-Paratethys Sea in Central Asia (Tarim and Tajik basins): Role of intensified tectonic activity at ca. 41 Ma[J]. Basin Research, 2019, 31(3): 461-486.
[132]	Jiang L L, Li Y T. Analysis of landscape pattern evolution and impact factors in the Mainstream Basin of the Tarim River from 1980 to 2020[J]. Hydrology, 2024, 11(7): 93.
[133]	Boucot A J, Xu C, Scotese C R, et al. Phanerozoic paleoclimate: An atlas of lithologic indicators of climate[M]. Tulsa: SEPM, 2013.
[134]	Fang X, Deyan Z, Kang C, et al. Early Cretaceous paleoclimate characteristics of China: Clues from continental climate‐indicative sediments[J]. Acta Geologica Sinica‐English Edition, 2015, 89(4): 1307-1318.
[135]	邓胜徽，卢远征，赵怡，等. 中国侏罗纪古气候分区与演变[J]. 地学前缘，2017，24（1）：106-142. Deng Shenghui, Lu Yuanzheng, Zhao Yi, et al. The Jurassic palaeoclimate regionalization and evolution of China[J]. Earth Science Frontiers, 2017, 24(1): 106-142.
[136]	徐斌，向芳，李树霞. 中国晚白垩世陆相气候敏感性沉积物分布对古气候指示[J]. 煤田地质与勘探，2021，49（5）：190-199. Xu Bin, Xiang Fang, Li Shuxia. Distribution characteristics and paleo-climatic significance of continental climate-sensitive sediments in the Late Cretaceous in China[J]. Coal Geology Exploration, 2021, 49(5): 190-199.
[137]	Sakai H. Geology of the Tansen Group of the Lesser Himalaya in Nepal[J]. Memoirs of the Faculty of Science, Kyūsyū University. Series D, Geology, 1983, 25(1): 27-74.
[138]	Ravikant V, Wu F Y, Ji W Q. U–Pb age and Hf isotopic constraints of detrital zircons from the Himalayan foreland Subathu sub-basin on the Tertiary palaeogeography of the Himalaya[J]. Earth and Planetary Science Letters, 2011, 304(3/4): 356-368.
[139]	Colleps C L, McKenzie N R, Horton B K, et al. Sediment pro-venance of pre- and post-collisional Cretaceous-Paleogene strata from the frontal Himalaya of northwest India[J]. Earth and Planetary Science Letters, 2020, 534: 116079.
[140]	Matsumaru K, Sakai H. Nummulites and Assilina from Tansen area, Palpa district, the Nepal Lesser Himalayas[C]//Transactions and proceedings of the paleontological society of Japan. New Series. Palaeontological Society of Japan, 1989, 1989(154): 68-76.
[141]	Bera M K, Sarkar A, Chakraborty P P, et al. Marine to continental transition in Himalayan foreland[J]. GSA Bulletin, 2008, 120(9/10): 1214-1232.
[142]	Ahmad S, Kroon D, Rigby S, et al. Paleogene Nummulitid biostratigraphy of the Kohat and Potwar basins in north-western Pakistan with implications for the timing of the closure of eastern Tethys and uplift of the western Himalayas[J]. Stratigraphy, 2017, 13(4): 277-301.
[143]	Vail P R, Mitchum R M, Thompson S. Seismic stratigraphy and global changes of sea level, part 4: global cycles of relative changes of sea level[J]. AAPG Bulletin, 1977, 26: 83-97.
[144]	Haq B U, Hardenbol J A N, Vail P R. Chronology of fluctuating sea levels since the Triassic[J]. Science, 1987, 235(4793): 1156-1167.
[145]	Miller K G, Kominz M A, Browning J V, et al. The Phanerozoic record of global sea-level change[J]. Science, 2005, 310(5752): 1293-1298.
[146]	孙镇城，杨革联，乔子真，等. 我国咸化湖泊沉积中钙质超微化石特征及其地质意义[J]. 古地理学报，2002，4（2）：56-63. Sun Zhencheng, Yang Gelian, Qiao Zizhen, et al. Characteristics and geologic significance of calcareous nanofossils in sediments of terrestrial salinized lakes[J]. Journal of Palaeogeography, 2002, 4(2): 56-63.
[147]	Ma J, Wu C D, Uveges B T, et al. Biomarkers reveal Eocene marine incursions into the Qaidam Basin, north Tibetan Plateau[J]. Organic Geochemistry, 2022, 166: 104380.
[148]	郝诒纯，曾学鲁，裘松余，等. 新疆塔里木盆地中新世有孔虫及其地质意义[J]. 中国地质科学院院报，1982（4）：69-79，81-82. Hao Yichun, Zeng Xuelu, Qiu Songyu, et al. Miocene foraminifera of Tarim Basin, Xinjiang and their geological significance[J]. Bulletin of the Chinese Academy of Geological Sciences, 1982(4): 69-79, 81-82.
[149]	裘松余. 塔里木盆地中中新世有孔虫群及其生态和生油性分析[J]. 石油实验地质，1990，12（1）：87-97. Qiu Songyu. The analysis on Middle Miocene foraminiferal fauna of the Tarim Basin and their ecology, property of stratigraphic oil- source potential[J]. Experimental Petroleum Geology, 1990, 12(1): 87-97.
[150]	郭宪璞，丁孝忠，何希贤，等. 塔里木盆地中新生代海侵和海相地层研究的新进展[J]. 地质学报，2002，76（3）：299-307. Guo Xianpu, Ding Xiaozhong, He Xixian, et al. New pro-gress in the study of marine transgressional events and marine strata of the Meso-Cenozoic in the Tarim Basin[J]. Acta Geologica Sinica, 2002, 76(3): 299-307.
[151]	Ritts B D, Yue Y J, Graham S A, et al. From sea level to high elevation in 15 million years: Uplift history of the northern Tibetan Plateau margin in the Altun Shan[J]. American Journal of Science, 2008, 308(5): 657-678.
[152]	Ji J L, Zhang K X, Clift P D, et al. High-resolution magnetostratigraphic study of the Paleogene-Neogene strata in the northern Qaidam Basin: Implications for the growth of the northeastern Tibetan Plateau[J]. Gondwana Research, 2017, 46: 141-155.
[153]	Wang W T, Zheng W J, Zhang P Z, et al. Expansion of the Tibetan Plateau during the Neogene[J]. Nature Communications, 2017, 8(1): 15887.
[154]	Ge M J, Wu L, Wu S T, et al. Late Oligocene formation of the Qaidam Basin revealed by calcite U-Pb dating: Insights into the northward growth of Tibetan Plateau[J]. Earth and Planetary Science Letters, 2025, 653: 119208.
[155]	Zeng D, Ding L, Spicer R A, et al. Direct dating of Qaidam Basin stratigraphy, northern Tibet[J]. Earth and Planetary Science Letters, 2025, 664: 119440.
[156]	范和平，杨金泉，张平. 藏北地区的晚侏罗世地层[J]. 地层学杂志，1988，12（1）：66-70. Fan Heping, Yang Jinquan, Zhang Ping. The Late Jurassic strata in the northern Tibet region[J]. Journal of Stratigraphy, 1988, 12(1): 66-70.
[157]	伊海生，林金辉，赵兵，等. 藏北羌塘地区地层新资料[J]. 地质论评，2003，49（1）：59-65. Yi Haisheng, Lin Jinhui, Zhao Bing, et al. New biostratigraphic data of the Qiangtang area in the northern Tibetan Plateau[J]. Geological Review, 2003, 49(1): 59-65.
[158]	方德庆，梁定益. 北羌塘盆地中部上侏罗统研究新进展[J]. 地层学杂志，2000，24（2）：163-167. Fang Deqing, Liang Dingyi. New advances in the research on the Upper Jurassic in the middle of the north Qiangtang Basin[J]. Journal of Stratigraphy, 2000, 24(2): 163-167.
[159]	王剑，付修根，杜安道，等. 羌塘盆地胜利河海相油页岩地球化学特征及Re-Os定年[J]. 海相油气地质，2007，12（3）：21-26. Wang Jian, Fu Xiugen, Du Andao, et al. Organic geochemistry and Re-Os dating of marine oil shale in Shenglihe area, northern Tibet, China[J]. Marine Origin Petroleum Geology, 2007, 12(3): 21-26.
[160]	吴滔，熊兴国，易成兴，等. 北羌塘坳陷胜利河组膏岩沉积环境[J]. 新疆石油地质，2010，31（4）：376-378. Wu Tao, Xiong Xingguo, Yi Chengxing, et al. Gypsolyte sedimentary environment of Upper Jurassic-Lower Cretaceous in Shenglihe area in northern Qiangtang Basin[J]. Xinjiang Petroleum Geology, 2010, 31(4): 376-378.
[161]	付修根，王剑，曾玉红，等. 羌塘中生代盆地大洋缺氧事件及全球对比[J]. 地质论评，2020，66（5）：1130-1142. Fu Xiugen, Wang Jian, Zeng Yuhong, et al. Oceanic anoxic events in the Mesozoic Qiangtang Basin and global comparison[J]. Geological Review, 2020, 66(5): 1130-1142.
[162]	Wang X C, Li J. Re-Os dating of the Shenglihe marine oil shale, north Tibet:A development method for direct dating crude oil[J]. Second Annual Conference for Key Laboratory for Sedimentary Carbon-Isotope Record and Paleoceanographic Changes Prior to the OAE 1a Basin and Oil and Gas Resources, 2013, 6 Abstract.
[163]	Fu X G, Wang J, Wen H G, et al. Carbon-isotope record and paleoceanographic changes prior to the OAE 1a in the eastern Tethys: Implication for the accumulation of organic-rich sediments[J]. Marine and Petroleum Geology, 2020, 113: 104049.
[164]	Yin J R. The age of the Bailongbinghe Formation and the oil shales in northern Qiangtang (North Tibet)[J]. PalZ, 2023, 97(1): 179-207.
[165]	徐钰林. 西藏南部早第三纪钙质超微化石及东特提斯在西藏境内的封闭时限[J]. 现代地质，2000，14（3）：255-262. Xu Yulin. Early Tertiary calcareous nannofossils from southern Tibet and the closing time of East Tethys in Tibet[J]. Geoscience, 2000, 14(3): 255-262.
[166]	Zhang Q H, Willems H, Ding L. Evolution of the Paleocene-Early Eocene larger benthic foraminifera in the Tethyan Himalaya of Tibet, China[J]. International Journal of Earth Sciences, 2013, 102(5): 1427-1445.
[167]	万晓樵. 西藏白垩纪—早第三纪有孔虫与特提斯—喜马拉雅海的演化[J]. 微体古生物学报，1990，7（2）：169-186. Wan Xiaoqiao. Cretaceous-Early Tertiary foraminifera of Xizang (Tibet) and evolution of the Tethys-Himalayan sea[J]. Acta Micropalaeontologica Sinica, 1990, 7(2): 169-186.