[1] 曹珂,马继彪,陈安清,等. 2007. 白垩纪陆相红层及其古温度的氧同位素重建方法探讨[J]. 地质与资源,16(1):50-55.

Cao Ke, Ma Jibiao, Chen Anqing, et al. 2007. Cretaceous continental red beds and the reconstruction of paleotemperature by oxygen isotope[J]. Geology and Resources, 16(1): 50-55.
[2] 曹珂,王猛. 2009. 沉积记录对白垩纪中国大陆古气候模拟的约束[J]. 地学前缘,16(5):29-36.

Cao Ke, Wang Meng. 2009.Constraints of sedimentary records on Cretaceous paleoclimate simulation in China mainland[J]. Earth Science Frontiers, 2009. 16(5): 29-36.
[3] 常华进,储雪蕾,冯连君,等. 2009. 氧化还原敏感微量元素对古海洋沉积环境的指示意义[J]. 地质论评,55(1):91-99.

Chang Huajin, Chu Xuelei, Feng Lianjun, et al. 2009. Redox sensitive trace elements as paleoenvironments proxies[J]. Geological Review, 55(1): 91-99.
[4] 陈金牛,毛学刚,师永辉,等. 2020. 闽西晚白垩世红层的古环境探究[J]. 地球物理学报,63(4):1553-1568.

Chen Jinniu, Mao Xuegang, Shi Yonghui, et al. 2020. Study on the Late Cretaceous paleoenvironment documented by red beds in the western Fujian province[J]. Chinese Journal of Geophysics, 63(4): 1553-1568.
[5] 陈亮,刘春莲,庄畅,等. 2009. 三水盆地古近系下部湖相沉积的稀土元素地球化学特征及其古气候意义[J]. 沉积学报,27(6):1155-1162.

Chen Liang, Liu Chunlian, Zhuang Chang, et al. 2009. Rare earth element records of the Lower Paleogene sediments in the Sanshui Basin and their paleoclimate implications[J]. Acta Sedimentologica Sinica, 27(6): 1155-1162.
[6] 陈留勤,李鹏程,郭福生,等. 2019. 粤北丹霞盆地晚白垩世丹霞组沉积相及古气候意义[J]. 沉积学报,37(1):17-29.

Chen Liuqin, Li Pengcheng, Guo Fusheng, et al. 2019. Facies analysis and paleoclimate implications of the Late Cretaceous Danxia Formation in the Danxia Basin, northern Guangdong province, South China[J]. Acta Sedimentologica Sinica, 37(1): 17-29.
[7] 陈丕基. 1997. 晚白垩世中国东南沿岸山系与中南地区的沙漠和盐湖化[J]. 地层学杂志,21(3):203-213.

Chen Piji. 1997. Coastal mountains of SE China, desertization and saliniferous lakes of central China during the Upper Cretaceous[J]. Journal of Stratigraphy, 21(3): 203-213.
[8] 傅寒晶,简星,梁杭海. 2021. 硅酸盐化学风化强度评估的沉积物指标与方法研究进展[J]. 古地理学报,23(6):1192-1209.

Fu Hanjing, Jian Xing, Liang Hanghai. 2021. Research progress of sediment indicators and methods for evaluation of silicate chemical weathering intensity[J]. Journal of Palaeogeography, 23(6): 1192-1209.
[9] 高远,王成善,黄永建,等. 2017. 大陆科学钻探开展古气候研究进展[J]. 地学前缘,24(1):229-241.

Gao Yuan, Wang Chengshan, Huang Yongjian, et al. 2017. Progress in the study of paleoclimate change in continental scientific drilling projects[J]. Earth Science Frontiers, 24(1): 229-241.
[10] 许汉森、李水林、刘建雄,等. (广东省佛山地质局,广东省地质勘查局七〇六地质大队). 2008. 丹霞山世界地质公园丹霞地貌地质成因研究[R].

Xu Hansen, Li Shuilin, Liu Jianxiong, et al.(Foshan Geological Bureau of Guangdong Province, 706 Geological Brigade, Guangdong Geological Exploration Bureau). 2008. Study on geological genesis of Danxia geomorphology in Dan-xiashan Geopark[R].
[11] 何岸北. 2022. 东南沿海古海岸山脉演化:永安盆地晚中生代沉积及古气候响应[D]. 北京:中国科学院大学:1-108.

He Anbei. 2022. Evolution of paleo-coastal mountains along the southeast coast: Sedimentation and paleoclimate response in Yong’an Basin of the Late Mesozoic[D]. Beijing: University of Chinese Academy of Sciences: 1-108.
[12] 黄进. 2010. 丹霞山地貌[M]. 北京:科学出版社:1-239.

Huang Jin.2010. The landform of the Danxiashan[M]. Beijing: Science Press: 1-239.
[13] 黄乐清,黄建中,罗来,等. 2019. 湖南衡阳盆地东缘白垩系风成沉积的发现及其古环境意义[J]. 沉积学报,37(4):735-748.

Huang Leqing, Huang Jianzhong, Luo Lai, et al. 2019. The discovery of Cretaceous eolian deposits at the eastern margin of the Hengyang Basin, Hunan, and its paleoenvironmental significance[J]. Acta Sedimentologica Sinica, 37(4): 735-748.
[14] 江新胜,潘忠习,付清平. 2000.白垩纪时期东亚大气环流格局初探[J]. 中国科学:地球科学,30(5):526-532.

Jiang Xinsheng, Pan Zhongxi, Fu Qingping. 2000. Primary study on pattern of general circulation of atmosphere before uplift of the Tibetan Plateau in eastern Asia[J]. Science China Earth Sciences, 30(5): 526-532.
[15] 李祥辉,陈斯盾,曹珂,等. 2009. 浙闽地区白垩纪中期古土壤类型与古气候[J]. 地学前缘,16(5):63-70.

Li Xianghui, Chen Sidun, Cao Ke, et al. 2009. Paleosols of the mid-Cretaceous: A report from Zhejiang and Fujian, SE China[J]. Earth Science Frontiers, 16(5): 63-70.
[16] 李祥辉,张朝凯,王尹,等. 2018. 华南晚中生代陆相地层年代及关系研究[J]. 地质学报,92(6):1107-1130.

Li Xianghui, Zhang Chaokai, Wang Yin, et al. 2018. Geochronostratigraphy and relationship of the Late Mesozoic terrestrial lithostratigraphic units in South China[J]. Acta Geologica Sinica, 92(6): 1107-1130.
[17] 李余亮. 2018. 广东省韶关市丹霞盆地长坝组沉积特征与古气候研究[D]. 南昌:东华理工大学:1-49.

Li Yuliang. 2018. Sedimentary characteristics and paleoclimate of the Changba Formation in the Danxia Basin, Shaoguan city, Guangdong province, South China[D]. Nanchang: East China University of Technology: 1-49.
[18] 梁西文. 2008. 中扬子区晚三叠世—新近纪层序岩相古地理演化研究[D]. 成都:成都理工大学:1-167.

Liang Xiwen. 2008. Study on lithofacies paleographic evolution of Late Triassic-Neogene sequence in mid-Yangtze region[D]. Chengdu: Chengdu University of Technology: 1-167.
[19] 林治家,陈多福,刘芊. 2008. 海相沉积氧化还原环境的地球化学识别指标[J]. 矿物岩石地球化学通报,27(1):72-80.

Lin Zhijia, Chen Duofu, Liu Qian. 2008. Geochemical indices for redox conditions of marine sediments[J]. Bulletin of Mineralogy, Petrology and Geochemistry, 27(1): 72-80.
[20] 刘富军. 2020. 广东丹霞山丹霞地貌成景地层沉积环境与地貌演化[D]. 成都:成都理工大学:1-127.

Liu Fujun. 2020. Sedimentary environment and geomorphologic evolution of Danxia landscape layer from Danxiashan, Guangdong province[D]. Chengdu: Chengdu University of Technology: 1-127.
[21] 刘耕武,李伟同,张清如,等. 2006. 江汉盆地渔洋组上部的古新世孢粉组合[J]. 古生物学报,45(1):60-68.

Liu Gengwu, Li Weitong, Zhang Qingru, et al. 2006. Paleocene palynoflora from upper member of Yuyan Formation, Jianghan Basin of central China[J]. Acta Palaeontologica Sinica, 45(1): 60-68.
[22] 刘玲,李祥辉,王尹,等. 2012. 浙闽地区白垩纪早中期黏土矿物组成特征及其古气候显示[J]. 沉积学报,30(1):120-127.

Liu Ling, Li Xianghui, Wang Yin, et al. 2012. The early-mid Cretaceous changes of clay mineral composition from Zhejiang and Fujian provinces, SE China: Indications to paleoclimate changes[J]. Acta Sedimentologica Sinica, 30(1): 120-127.
[23] 刘芮岑. 2018. 湖南茶陵盆地晚白垩世—古新世古气候分析[D]. 南京:南京大学:1-60.

Liu Ruicen. 2018. limate of the Late Cretaceous-Paleocene in the Chaling Basin, Hunan, South China[D]. Nanjing: Nanjing University: 1-60.
[24] 彭华. 2000. 中国丹霞地貌研究进展[J]. 地理科学,20(3):203-211.

Peng Hua. 2000. A survey of the Danxia landform research in China[J]. Scientia Geographica Sinica, 20(3): 203-211.
[25] 彭华. 2004. 中国红石公园丹霞山[M]. 北京:地质出版社:1-120.

Peng Hua. 2004. The red stone park of China[M]. Beijing: Geological Publishing House: 1-120.
[26] 彭华,潘志新,闫罗彬,等. 2013. 外红层与丹霞地貌研究述评[J]. 地理学报,68(9):1170-1181.

Peng Hua, Pan Zhixin, Yan Luobin, et al. 2013. A review of the research on red beds and Danxia landform[J]. Acta Geographica Sinica, 68(9): 1170-1181.
[27] 彭华,邱卓炜,潘志新. 2014. 山顺层洞穴风化特征的试验研究[J]. 地理科学,34(4):454-463.

Peng Hua, Qiu Zhuowei, Pan Zhixin. 2014. Experimental study on the weathering features of bedding caves at Mt. Danxiashan[J]. Scientia Geographica Sinica, 34(4): 454-463.
[28] 史月欣. 2023. 丹霞盆地晚白垩世红层沉积特征及地球化学研究[D]. 南昌:东华理工大学:1-53.

Shi Yuexin. 2023. Sedimentary characteristics and geochemistry of Late Cretaceous red beds in Danxia Basin[D]. Nanchang: East China University of Technology: 1-53.
[29] 田云涛,秦咏辉,胡杰,等. 2022. 白垩纪以来东亚地貌演化与构造驱动:来自沉积盆地与构造变形的记录[J]. 大地构造与成矿学,46(3):471-482.

Tian Yuntao, Qin Yonghui, Hu Jie, et al. 2022. Cretaceous-Cenozoic first-order landscape evolution of the East Asia and its tectonic drivers: A synthesis of sedimentary and structural records[J]. Geotectonica et Metallogenia, 46(3): 471-482.
[30] 汪品先. 2005. 新生代亚洲形变与海陆相互作用[J]. 地球科学:中国地质大学学报,30(1):1-18.

Wang Pinxian. 2005. Cenozoic deformation and history of sea-land interactions in Asia[J]. Earth Science: Journal of China University of Geosciences, 30(1): 1-18.
[31] 汪齐连,赵志琦,刘丛强,等. 2006. 天然样品中锂的分离及其同位素比值的测定[J]. 分析化学,34(6):764-768.

Wang Qilian, Zhao Zhiqi, Liu Congqiang, et al. 2006. Separation and isotopic determination of lithium in natural samples[J]. Chinese Journal of Analytical Chemistry, 34(6): 764-768.
[32] 王成善,胡修棉. 2005. 白垩纪世界与大洋红层[J]. 地学前缘,12(2):11-21.

Wang Chengshan, Hu Xiumian. 2005. Cretaceous world and oceanic red beds[J]. Earth Science Frontiers, 12(2): 11-21.
[33] 王成善,胡修棉,李祥辉. 1999. 古海洋溶解氧与缺氧和富氧问题研究[J]. 海洋地质与第四纪地质,19(3):39-48.

Wang Chengshan, Hu Xiumian, Li Xianghui. 1999. Dissolved oxygen in palaeo-ocean: Anoxic events and high-oxic problems[J]. Marine Geology and Quaternary Geology, 19(3): 39-48.
[34] 王开发,张玉兰,蒋辉,等. 1989. 浙江白垩—第三纪孢粉组合及其古植被、古气候[J]. 古生物学报,28(5):653-662.

Wang Kaifa, Zhang Yulan, Jiang Hui, et al. 1989. Cretaceous-Tertiary sporo-pollen assemblages of Zhejiang with their paleovegetation and paleoclimate[J]. Acta Palaeontologica Sinica, 28(5): 653-662.
[35] 王文艳,刘秀铭,马明明,等. 2016. 南雄盆地白垩纪红层沉积环境分析[J]. 亚热带资源与环境学报,11(3):29-37.

Wang Wenyan, Liu Xiuming, Ma Mingming, et al. 2016. Sedimentary environment of Cretaceous red beds in Nanxiong Basin, Guangdong pro-vince[J]. Journal of Subtropical Resources and Environment, 11(3): 29-37.
[36] 王尹,李祥辉,周勇,等. 2015. 南雄盆地晚白垩世—古新世陆源沉积组份变化的古气候指示[J]. 沉积学报,33(1):116-123.

Wang Yin, Li Xianghui, Zhou Yong, et al. 2015. Paleoclimate indication of terrigenous clastic rock’s component during the Late Cretaceous-Early Paleocene in the Nanxiong Basin[J]. Acta Sedimentologica Sinica, 33(1): 116-123.
[37] 王宇佳. 2019. 江西广丰晚白垩世周田组沉积特征与古气候分析[D]. 南昌:东华理工大学:1-55.

Wang Yujia. 2019. Sedimentary characteristics and paleoclimate of the Zhoutian Formation in the Guangfeng Basin of Jiangxi province[D]. Nanchang: East China University of Technology: 1-55.
[38] 魏巍, Algeo T J,陆永潮,等. 2021. 古盐度指标与渤海湾盆地古近系海侵事件初探[J]. 沉积学报,39(3):571-592.

Wei Wei, Algeo T J, Lu Yongchao, et al. 2021. Paleosalinity proxies and marine incursions into the Paleogene Bohai Bay Basin lake system, northeastern China[J]. Acta Sedimentologica Sinica, 39(3): 571-592.
[39] 文星跃,黄成敏,王成善. 2015. 重要环境与气候变化事件:深时古土壤的记录与响应[J]. 土壤通报,46(5):1272-1280.

Wen Xingyue, Huang Chengmin, Wang Chengshan. 2015. Critical events in paleoenvironmental and paleoclimatic change revealed by deep-time paleosols[J]. Chinese Journal of Soil Science, 46(5): 1272-1280.
[40] 巫建华,周维勋,章邦桐. 2002. 江西及广东北部中生代晚期地层层序和时代:兼论《江西省岩石地层》中存在的问题[J]. 地质论评,48(1):44-53.

Wu Jianhua, Zhou Weixun, Zhang Bangtong. 2002. Stratigraphical sequence and geochronology of the Late Mesozoic Era in Jiangxi province and northern Guangdong province[J]. Geological Review, 48(1): 44-53.
[41] 吴根耀. 2006. 白垩纪:中国及邻区板块构造演化的一个重要变换期[J]. 中国地质,33(1):64-77.

Wu Genyao. 2006. Cretaceous: A key transition period of the plate tectonic evolution in China and its adjacent areas[J]. Geology in China, 33(1): 64-77.
[42] 吴甲添,刘建雄,廖示庭. 2001. 丹霞盆地地质特征和演化[J]. 中国区域地质,20(3):274-279.

Wu Jiatian, Liu Jianxiong, Liao Shi-ting. 2001. Geological characteristics, evolution of the Danxia Basin[J]. Regional Geology of China, 20(3): 274-279.
[43] 吴起俊. 1994. 丹霞盆地的基本地质特征[C]//经济地理,第二届丹霞地貌旅游开发学术研讨会论文集(增刊1):1-21.

Wu Qijun. 1994. Basic geological characteristics of Danxia Basin[C]//Proceedings of the 2nd Symposium on Danxia Landform and Tourism Development. Economic Geography( Suppl. 1): 1-21.
[44] 向芳,宋见春,罗来,等. 2009. 白垩纪早期陆相特殊沉积的分布特征及气候意义[J]. 地学前缘,16(5):48-62.

Xiang Fang, Song Jianchun, Luo Lai, et al. 2009. Distribution characteristics and climate significance of continental special deposits in the Early Cretaceous[J]. Earth Science Frontiers, 16(5): 48-62.
[45] 熊小辉,肖加飞. 2011. 沉积环境的地球化学示踪[J]. 地球与环境,39(3):405-414.

Xiong Xiaohui, Xiao Jiafei. 2011. Geochemical indicators of sedimentary environments: A summary[J]. Earth and Environment, 39(3): 405-414.
[46] 徐行,葛同明,肖晖. 1990. 丹霞盆地红层时代的初探:古地磁研究的新证据[J]. 成都地质学院学报,17(2):79-86.

Xu Xing, Ge Tongming, Xiao Hui. 1990. Preliminary search on the age for red beds in Danxia Basin: New evidence of paleomagnetic study[J]. Journal of Chengdu College of Geology, 17(2): 79-86.
[47] 叶婷婷. 2023. 华南地区新生代陆相气候敏感沉积物时空分布特征与古气候演化规律[D]. 南昌:东华理工大学:1-63.

Ye Tingting. 2023. Spatiotemporal distribution characteristics of Cenozoic continental climate-sensitive deposits and paleoclimate evolution in South China[D]. Nanchang: East China University of Technology: 1-63.
[48] 张鸿禹,杨文涛. 2023. 陆相细粒沉积岩与古土壤深时气候分析方法综述[J]. 沉积学报,41(2):333-348.

Zhang Hongyu, Yang Wentao. 2023. Research status of deep-time paleoclimate analysis methods for terrestrial pulveryte and paleosols[J]. Acta Sedimentologica Sinica, 41(2): 333-348.
[49] 张显球. 1992. 丹霞盆地白垩系的划分与对比[J]. 地层学杂志,16(2):81-95.

Zhang Xianqiu. 1992. Division and correlation of the Cretaceous rocks in the Danxia Basin[J]. Journal of Stratigraphy, 16(2): 81-95.
[50] 张显球,林小燕. 2013. 粤北丹霞盆地白垩系长坝组的介形类动物群[J]. 微体古生物学报,30(1):58-86.

Zhang Xianqiu, Lin Xiaoyan. 2013. Cretaceous ostracods from the Changba Formation in the Danxia Basin of northern Guangdong province[J]. Acta Micropalaeontologica Sinica, 30(1): 58-86.
[51] 张哲. 2018. 三水盆地下白垩统—始新统粘土矿物特征及其对区域构造—气候事件的响应[D]. 北京:中国地质大学(北京):1-64.

Zhang Zhe. 2018. Clay mineral characteristics of Sanshui Basin from Lower Cretaceous to Eocene and their response to tectonic activities and climate changes in the region[D]. Beijing: China University of Geosciences (Beijing): 1-64.
[52] 周红健. 1990. 广东丹霞盆地地层的划分及时代归属[J]. 广东地质,5(4):51-58.

Zhou Hongjian. 1990. Stratigraphic division and age attribution of the Danxia Basin, Guangdong province[J]. Guangdong Geology, 5(4): 51-58.
[53] 周炼,苏洁,黄俊华,等. 2011. 判识缺氧事件的地球化学新标志:钼同位素[J]. 中国科学:地球科学,41(3):309-319.

Zhou Lian, Su Jie, Huang Junhua, et al. 2011. A new paleoenvironmental index for anoxic events-Mo isotopes in black shales from Upper Yangtze marine sediments[J]. Science China Earth Sciences, 41(3): 309-319.
[54] 朱建明,朱祥坤,黄方. 2008. 钼的稳定同位素体系及其地质应用[J]. 岩石矿物学杂志,27(4):353-360.

Zhu Jianming, Zhu Xiangkun, Huang Fang. 2008. The systematics of molybdenum stable isotope and its application to earth science[J]. Acta Petrologica et Mineralogica, 27(4): 353-360.
[55] 朱立平,王君波,林晓,等. 2007. 西藏纳木错深水湖芯反映的8.4 ka以来气候环境变化[J]. 第四纪研究,27(4),588-597.

Zhu Li-ping, Wang Junbo, Lin Xiao, et al. 2007. Environmental changes reflected by core sediments since 8.4 ka in Nam Co, central Tibet of China[J]. Quaternary Sciences, 27(4): 588-597.
[56] Bai J H, Wu C, Wu H, et al. 2024. δ 142Ce minus δ 146Nd value as a redox indicator in Earth's surface environments[J]. Earth and Planetary Science Letters, 629: 118597.
[57] Barling J, Arnold G L, Anbar A D. 2001. Natural mass-dependent variations in the isotopic composition of molybdenum[J]. Earth and Planetary Science Letters, 193(3/4): 447-457.
[58] Bau M, Dulski P. 1996. Distribution of yttrium and rare-earth elements in the Penge and Kuruman iron-formations, Transvaal Supergroup, South Africa[J]. Precambrian Research, 79(1/2): 37-55.
[59] Boucot A, Chen X, Scotese C, et al. 2009. Reconstruction of the Phanerozoic global paleoclimate[M]. Beijing: Science Press.
[60] Cao K. 2018. Cretaceous terrestrial deposits in China[J]. China Geology, 1(3): 402-414.
[61] Chen G H, Robertson A H F. 2020. User's guide to the interpretation of sandstones using whole-rock chemical data, exemplified by sandstones from Triassic to Miocene passive and active margin settings from the southern Neotethys in Cyprus[J]. Sedimentary Geology, 400: 105616.
[62] Chen L Q, Steel R J, Guo F S, et al. 2017. Alluvial fan facies of the Yongchong Basin: Implications for tectonic and paleoclimatic changes during Late Cretaceous in SE China[J]. Journal of Asian Earth Sciences, 134: 37-54.
[63] Chen Y, Meng J, Liu H, et al. 2022. Detrital zircons record the evolution of the Cathaysian coastal mountains along the South China margin[J]. Basin Research, 34(2): 688-701.
[64] Condie K C. 1993. Chemical composition and evolution of the upper continental crust: Contrasting results from surface samples and shales[J]. Chemical Geology, 104(1/2/3/4): 1-37.
[65] Cullers R L. 1995. The controls on the major- and trace-element evolution of shales, siltstones and sandstones of Ordovician to Tertiary age in the Wet Mountains region, Colorado, U.S.A.[J]. Chemical Geology, 123(1/2/3/4): 107-131.
[66] Dellinger M, Bouchez J, Gaillardet J, et al. 2017. Tracing weathering regimes using the lithium isotope composition of detrital sediments[J]. Geology, 45(5): 411-414.
[67] Dellinger M, Gaillardet J, Bouchez J, et al. 2014. Lithium isotopes in large rivers reveal the cannibalistic nature of modern continental weathering and erosion[J]. Earth and Planetary Science Letters, 401: 359-372.
[68] Ding R X, Min K, Zou H P. 2019. Inversion of topographic evolution using low-T thermal history: A case study from coastal mountain system in southeastern China[J]. Gondwana Research, 67: 21-32.
[69] Dinis P A, Garzanti E, Hahn A, et al. 2020. Weathering indices as climate proxies. A step forward based on Congo and SW African river muds[J]. Earth-Science Reviews, 201: 103039.
[70] Fedo C M, Wayne Nesbitt H, Young G M. 1995. Unraveling the effects of potassium metasomatism in sedimentary rocks and paleosols, with implications for paleoweathering conditions and provenance[J]. Geology, 23(10): 921-924.
[71] Floyd P A, Leveridge B F. 1987. Tectonic environment of the Devonian Gramscatho Basin, south Cornwall: Framework mode and geochemical evidence from turbiditic sandstones[J]. Journal of the Geological Society, 144(4): 531-542.
[72] Frakes L A, Francis J E, Syktus J I. 1992. Climate modes of the Phanerozoic: The history of the earth's climate over the past 600 million years[M]. Cambridge: Cambridge University Press.
[73] Fujisaki W, Sawaki Y, Yamamoto S, et al. 2016. Tracking the redox history and nitrogen cycle in the pelagic Panthalassic deep ocean in the Middle Triassic to Early Jurassic: Insights from redox-sensitive elements and nitrogen isotopes[J]. Palaeogeography, Palaeo-climatology, Palaeoecology, 449: 397-420.
[74] Hu X M, Jansa L, Wang C S, et al. 2005. Upper Cretaceous oceanic red beds (CORBs) in the Tethys: Occurrences, lithofacies, age, and environments[J]. Cretaceous Research, 26(1): 3-20.
[75] Hu Z C, Gao S. 2008. Upper crustal abundances of trace elements: A revision and update[J]. Chemical Geology, 253(3/4): 205-221.
[76] Jones B, Manning D A C. 1994. Comparison of geochemical indices used for the interpretation of palaeoredox conditions in ancient mudstones[J]. Chemical Geology, 111(1/2/3/4): 111-129.
[77] Li J, Liang X R, Zhong L F, et al. 2014. Measurement of the isotopic composition of molybdenum in geological samples by MC‐ICP‐MS using a novel chromatographic extraction technique[J]. Geostandards and Geoanalytical Research, 38(3): 345-354.
[78] Li M S, Huang C J, Ogg J, et al. 2019. Paleoclimate proxies for cyclostratigraphy: Comparative analysis using a Lower Triassic marine section in South China[J]. Earth-Science Reviews, 189: 125-146.
[79] Li S, Gaschnig R M, Rudnick R L. 2016. Insights into chemical weathering of the upper continental crust from the geochemistry of ancient glacial diamictites[J]. Geochimica et Cosmochimica Acta, 176: 96-117.
[80] Li S, Nie J S, Ren X P, et al. 2023. Increased primary mineral dissolution control on a terrestrial silicate lithium isotope record during the Middle Miocene climate optimum[J]. Geochimica et Cosmochimica Acta, 348: 41-53.
[81] Liu H Y, Sun H, Xiao Y L, et al. 2019. Lithium isotope systematics of the Sumdo Eclogite, Tibet: Tracing fluid/rock interaction of subducted low-T altered oceanic crust[J]. Geochimica et Cosmochimica Acta, 246: 385-405.
[82] McLennan S M. 1993. Weathering and global denudation[J]. The Journal of Geology, 101(2): 295-303.
[83] McLennan S M, Hemming S, McDaniel D K, et al. 1993. Geochemical approaches to sedimentation, provenance, and tectonics[C]//Johnsson M J, Basu A. Processes controlling the composition of clastic sediments. Geological Society of America, Special Papers, 284: 21-40.
[84] McLennan S M, Taylor S R. 1984. Archaean sedimentary rocks and their relation to the composition of the Archaean continental crust[M]//Kröner A, Hanson G N, Goodwin A M. Archaean geochemistry: The origin and evolution of the Archaean continental crust. Berlin: Springer: 47-72.
[85] Mude S N, Parcha S K, Pandey S, et al. 2019. Geochemistry, provenance, compositional maturity of Mastani Lake sediments, India[J]. Journal of Geosciences Research, 4(2): 143-154.
[86] Nesbitt H W, Markovics G, Price R C. 1980. Chemical processes affecting alkalis and alkaline earths during continental weathering[J]. Geochimica et Cosmochimica Acta, 44(11): 1659-1666.
[87] Nesbitt H W, Young G M. 1982. Early Proterozoic climates and plate motions inferred from major element chemistry of lutites[J]. Nature, 299(5885): 715-717.
[88] Nesbitt H W, Young G M. 1984. Prediction of some weathering trends of plutonic and volcanic rocks based on thermodynamic and kinetic considerations[J]. Geochimica et Cosmochimica Acta, 48(7): 1523-1534.
[89] Poulson R L, Siebert C, McManus J, et al. 2006. Authigenic molybdenum isotope signatures in marine sediments[J]. Geology, 34(8): 617-620.
[90] Rudnick R L, Gao S. 2003. Composition of the continental crust[C]//Holland H D, Turekian K K. Treatise on geochemistry. Oxford: Elsevier-Pergamon, 3: 1-64.
[91] Siebert C, McManus J, Bice A, et al. 2006. Molybdenum isotope signatures in continental margin marine sediments[J]. Earth and Planetary Science Letters, 241(3/4): 723-733.
[92] Siebert C, Nägler T F, von Blanckenburg F, et al. 2003. Molybdenum isotope records as a potential new proxy for paleoceanography[J]. Earth and Planetary Science Letters, 211(1/2): 159-171.
[93] Skelton P W, Spicer R A, Kelley S P, et al. 2003. The Cretaceous world[M]. Cambridge: Cambridge University Press.
[94] Tan J, Zhang L M, Wang C S, et al. 2020. Late Cretaceous provenance change in the Jiaolai Basin, East China: Implications for paleogeographic evolution of East Asia[J]. Journal of Asian Earth Sciences, 194: 104188.
[95] Tang Y J, Zhang H F, Ying J F. 2007. Review of the lithium isotope system as a geochemical tracer[J]. International Geology Review, 49(4): 374-388.
[96] Taylor S R, McLennan S M. 1985. The continental crust: Its composition and evolution: An examination of the geochemical record preserved in sedimentary rocks[M]. Oxford: Blackwell Scientific Publications.
[97] Teng F Z, Mcdonough W F, Rudnick R L, et al. 2004. Lithium isotopic composition and concentration of the upper continental crust[J]. Geochimica et Cosmochimica Acta, 68(20): 4167-4178.
[98] Teng X H, Fang X M, Kaufman A J, et al. 2019. Sedimentological and mineralogical records from drill core SKD1 in the Jianghan Basin, central China, and their implications for Late Cretaceous–Early Eocene climate change[J]. Journal of Asian Earth Sciences, 182: 103936.
[99] van der Sloot H A, Hoede D, Wijkstra J, et al. 1985. Anionic species of V, As, Se, Mo, Sb, Te and W in the Scheldt and Rhine estuaries and the Southern Bight (North Sea)[J]. Estuarine, Coastal and Shelf Science, 21(5): 633-651.
[100] Wei W, Algeo T J. 2020. Elemental proxies for paleosalinity analysis of ancient shales and mudrocks[J]. Geochimica et Cosmochimica Acta, 287: 341-366.
[101] Wright J, Schrader H, Holser W T. 1987. Paleoredox variations in ancient oceans recorded by rare earth elements in fossil apatite[J]. Geochimica et Cosmochimica Acta, 51(3): 631-644.
[102] Wronkiewicz D J, Condie K C. 1987. Geochemistry of Archean shales from the Witwatersrand Supergroup, South Africa: Source-area weathering and provenance[J]. Geochimica et Cosmochimica Acta, 51(9): 2401-2416.
[103] Yan L B, Peng H, Zhang S Y, et al. 2019. The spatial patterns of red beds and Danxia landforms: Implication for the formation factors–China[J]. Scientific Reports, 9(1): 1961.
[104] Young R W, Wray R A L, Young A R M. 2009. Sandstone landforms[M]. Cambridge: Cambridge University Press.