[1] Galloway W E, Hobday D K. Terrigenous clastic depositional systems: Applications to fossil fuel and groundwater resources[M]. 2nd ed. New York: Springer, 1996: 91-125.
[2] Dalrymple R W, Baker E K, Harris P T, et al. Sedimentology and stratigraphy of a tide-dominated, foreland-basin delta (Fly River, Papua New Guinea) [M]//Sidi F H, Nummedal D, Imbert P, et al. Tropical deltas of southeast Asia⁃Sedimentology, stratigraphy, and petroleum geology. Tulsa: SEPM Special Publication, 2003: 147-173.
[3] Perignon M, Adams J, Overeem I, et al. Dominant process zones in a mixed fluvial-tidal delta are morphologically distinct[J]. Earth Surface Dynamics, 2020, 8(3): 809-824.
[4] 牛文蕾. 潮控三角洲分汊河道形成过程和机制的地层记录研究:以长江口北港为例[D]. 上海:华东师范大学,2022:3-33.

Niu Wenlei. Stratigraphic records of the formation processes and mechanisms of distributary channels in tide-dominated river deltas: A case study in the North Channel, Yangtze River mouth[D]. Shanghai: East China Normal University, 2022: 3-33.
[5] Li C X, Chen Q Q, Zhang J Q, et al. Stratigraphy and paleoenvironmental changes in the Yangtze Delta during the Late Quaternary[J]. Journal of Asian Earth Sciences, 2000, 18(4): 453-469.
[6] Wang F, Nian X M, Wang J L, et al. Multiple dating approaches applied to the recent sediments in the Yangtze River (Changjiang) subaqueous delta[J]. The Holocene, 2018, 28(6): 858-866.
[7] Gugliotta M, Saito Y, Nguyen V L, et al. Tide- and river-generated mud pebbles from the fluvial to marine transition zone of the Mekong River delta, Vietnam[J]. Journal of Sedimentary Research, 2018, 88(9): 981-990.
[8] Gugliotta M, Saito Y, Nguyen V L, et al. Sediment distribution and depositional processes along the fluvial to marine transition zone of the Mekong River delta, Vietnam[J]. Sedimentology, 2019, 66(1): 146-164.
[9] Gugliotta M, Saito Y, Nguyen V L, et al. Process regime, salinity, morphological, and sedimentary trends along the fluvial to marine transition zone of the mixed-energy Mekong River delta, Vietnam[J]. Continental Shelf Research, 2017, 147: 7-26.
[10] Goodbred Jr S L, Kuehl S A. The significance of large sediment supply, active tectonism, and eustasy on margin sequence deve-lopment: Late Quaternary stratigraphy and evolution of the Ganges-Brahmaputra delta[J]. Sedimentary Geology, 2000, 133(3/4): 227-248.
[11] Braat L, Van Kessel T, Leuven J R F W, et al. Effects of mud supply on large-scale estuary morphology and development over centuries to millennia[J]. Earth Surface Dynamics, 2017, 5(4): 617-652.
[12] Taylor T R, Kittridge M G, Winefield P, et al. Reservoir quality and rock properties modeling-Triassic and Jurassic sandstones, greater Shearwater area, UK Central North Sea[J]. Marine and Petroleum Geology, 2015, 65: 1-21.
[13] van de Lageweg W I, Feldman H. Process-based modelling of morphodynamics and bar architecture in confined basins with fluvial and tidal currents[J]. Marine Geology, 2018, 398: 35-47.
[14] 刘雪萍, 卢双舫, 唐明明, 等. 河流—潮汐耦合控制下河口湾坝体沉积动力学数值模拟[J]. 地球科学, 2020, 46(8): 2944-2957.

Liu Xueping, Lu Shuangfang, Tang Mingming, et al. Numerical simulation of sedimentary dynamics to estuarine bar under the coupled fluvial-tidal control[J]. Earth Science, 2020, 46(8): 2944-2957.
[15] Tang M M, Zhang K X, Huang J X, et al. Facies and the architecture of estuarine tidal bar in the Lower Cretaceous mcmurray Formation, central Athabasca oil sands, Alberta, Canada[J]. Energies, 2019, 12(9): 1769.
[16] 冯文杰,吴胜和,张可,等. 曲流河浅水三角洲沉积过程与沉积模式探讨:沉积过程数值模拟与现代沉积分析的启示[J]. 地质学报,2017,91(9):2047-2064.

Feng Wenjie, Wu Shenghe, Zhang Ke, et al. Depositional process and sedimentary model of meandering-river shallow delta: Insights from numerical simulation and modern deposition[J]. Acta Geologica Sinica, 2017, 91(9): 2047-2064.
[17] 林承焰,陈柄屹,任丽华,等. 沉积数值模拟研究现状及实例[J]. 地质学报,2023,97(8):2756-2773.

Lin Chengyan, Chen Bingyi, Ren Lihua, et al. A review of depositional numerical simulation and a case study[J]. Acta Geologica Sinica, 2023, 97(8): 2756-2773.
[18] 张夏林,吴冲龙,周琦,等. 贵州超大型锰矿集区的多尺度三维地质建模[J]. 地球科学,2020,45(2):634-644.

Zhang Xialin, Wu Chonglong, Zhou Qi, et al. Multi-scale 3D modeling and visualization of super large manganese ore gathering area in Guizhou China[J]. Earth Science, 2020, 45(2): 634-644.
[19] Sloss L L. Stratigraphic models in exploration[J]. AAPG Bulletin, 1962, 46(7): 1050-1057.
[20] Schwarzacher W. Sedimentation in subsiding basins[J]. Nature, 1966, 210(5043): 1349-1350.
[21] Caldwell R L. The effect of grain size on river delta process and morphology[D]. Boston: Boston College, 2013: 9-40.
[22] 王杨君,尹太举,邓智浩,等. 水动力数值模拟的河控三角洲分支河道演化研究[J]. 地质科技情报,2016,35(1):44-52.

Wang Yangjun, Yin Taiju, Deng Zhihao, et al. Terminal distributary channels in fluvial-dominated delta systems from numerical simulation of hydrodynamics[J]. Geological Science and Technology Information, 2016, 35(1): 44-52.
[23] Schuurman F, Kleinhans M G. Bar dynamics and bifurcation evolution in a modelled braided sand-bed river[J]. Earth Surface Processes and Landforms, 2015, 40(10): 1318-1333.
[24] 张可,吴胜和,冯文杰,等. 砂质辫状河心滩坝的发育演化过程探讨:沉积数值模拟与现代沉积分析启示[J]. 沉积学报,2018,36(1):81-91.

Zhang Ke, Wu Shenghe, Feng Wenjie, et al. Discussion on evolution of bar in sandy braided river: Insights from sediment numerical simulation and modern bar[J]. Acta Sedimentologica Sinica, 2018, 36(1): 81-91.
[25] Schuurman F, Marra W A, Kleinhans M G. Physics-based modeling of large braided sand-bed rivers: Bar pattern formation, dynamics, and sensitivity[J]. Journal of Geophysical Research: Earth Surface, 2013, 118(4): 2509-2527.
[26] Granjeon D, Joseph P. Concepts and applications of a 3-D multiple lithology, diffusive model in stratigraphic modeling [M]. Tulsa: SEPM Special Publication, 1999: 197-210.
[27] Burgess P M. A brief review of developments in stratigraphic forward modelling, 2000-2009[M]//Roberts D G, Bally A W. Regional geology and tectonics: Principles of geologic analysis. Boston: Elsevier, 2012: 378-404.
[28] Lesser G R, Roelvink J A, Van Kester J A T M, et al. Development and validation of a three-dimensional morphological model[J]. Coastal Engineering, 2004, 51(8/9): 883-915.
[29] Nardin W, Fagherazzi S. The effect of wind waves on the development of river mouth bars[J]. Geophysical Research Letters, 2012, 39(12): L12607.
[30] Carballo R, Iglesias G, Castro A. Numerical model evaluation of tidal stream energy resources in the Ría de Muros (NW Spain)[J]. Renewable Energy, 2009, 34(6): 1517-1524.
[31] Griffiths C M, Dyt C, Paraschivoiu E, et al. SEDSIM in hydrocarbon exploration[M]//Merriam D F, Davis J C. Geologic modeling and simulation. Boston: Springer, 2001: 71-97.
[32] Granjeon D, Joseph P. Concepts and applications of a 3-D multiple lithology, diffusive model in stratigraphic modeling[M]//Harbaugh J W, Watney W L, Rankey E C, et al. Numerical experiments in stratigraphy: Recent advances in stratigraphic and sedimentologic computer simulations. Tulsa: SEPM Special Publication, 1999: 197-210.
[33] Zheng X Y, Mayerle R, Wang Y B, et al. Study of the wind drag coefficient during the storm Xaver in the German Bight using data assimilation[J]. Dynamics of Atmospheres and Oceans, 2018, 83: 64-74.
[34] 刘雪萍. 基于沉积动力学方法的潮控河口湾储层沉积模式研究[D]. 青岛:中国石油大学(华东),2021:22-24.

Liu Xueping. Study on sedimentary model of tide-dominated estuary reservoir based on sedimentary dynamics[D]. Qingdao: China University of Petroleum (East China), 2021: 22-24.
[35] Van Der Vegt H, Storms J E A, Walstra D J R, et al. Can bed load transport drive varying depositional behaviour in river delta environments?[J]. Sedimentary Geology, 2016, 345: 19-32.
[36] van Rijn L C. Estuarine and coastal sedimentation problems[J]. International Journal of Sediment Research, 2005, 20(1): 39-51.
[37] Xu Z H, Plink-Björklund P. Quantifying formative processes in river- and tide-dominated deltas for accurate prediction of future change[J]. Geophysical Research Letters, 2023, 50(20): 1-12.
[38] Nienhuis J H, Hoitink A J F, Törnqvist T E. Future change to tide-influenced deltas[J]. Geophysical Research Letters, 2018, 45(8): 3499-3507.