[1] 邓庆杰,康德江,胡明毅,等. 2020. 松辽盆地三肇凹陷南部泉头组四段浅水三角洲河道储层构型特征[J]. 石油与天然气地质,41(3):513-524.

Deng Qingjie, Kang Dejiang, Hu Mingyi, et al. 2020. Architecture of channel reservoirs of shallow-water delta in the 4th member of Cretaceous Quantou Formation in southern Sanzhao Sag, Songliao Basin[J]. Oil & Gas Geology, 41(3): 513-524.
[2] 杜威,纪友亮,李其海,等. 2020. 不同沉积过程尺度下正演数值模拟研究进展及油气地质意义[J]. 油气地质与采收率,27(2):62-71.

Du Wei, Ji Youliang, Li Qihai, et al. 2020. Sedimentary forward numerical modeling at different sedimentary scales: Progress and hydrocarbon significance[J]. Petroleum Geology and Recovery Efficiency, 27(2): 62-71.
[3] 冯文杰,吴胜和,张可,等. 2017. 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,91(9):2047-2064.

Feng Wenjie, Wu Shenghe, Zhang Ke, et al. 2017. Depositional process and sedimentary model of meandering-river shallow delta: Insights from numerical simulation and modern deposition[J]. Acta Geologica Sinica, 91(9): 2047-2064.
[4] 何文军,刘敏珠,吴俊军,等. 2018. 准噶尔盆地阜东斜坡阜19井区三叠系韭菜园子组沉积正演模拟[J]. 油气地质与采收率,25(6):7-15.

He Wenjun, Liu Minzhu, Wu Junjun, et al. 2018. Forward modeling of sedimentation in the Triassic Jiucaiyuanzi Formation in well Fu19 area of the Fudong slope, Junggar Basin[J]. Petroleum Geology and Recovery Efficiency, 25(6): 7-15.
[5] 胡迅,尹艳树,冯文杰,等. 2019. 深水浊积水道训练图像建立与多点地质统计建模应用[J]. 石油与天然气地质,40(5):1126-1134.

Hu Xun, Yin Yanshu, Feng Wenjie, et al. 2019. Establishment of training images of turbidity channels in deep waters and application of multi-point geostatistical modeling[J]. Oil & Gas Geology, 40(5): 1126-1134.
[6] 李家彪. 2012. 中国区域海洋学:海洋地质学[M]. 北京:海洋出版社:1-574.

Li Jiabiao. 2012. Regional oceanography of China seas: Marine geology[M]. Beijing: China Ocean Press: 1-574.
[7] 刘宝珺,谢俊,张金亮. 2004. 我国剩余油技术研究现状与进展[J]. 西北地质,37(4):1-6.

Liu Baojun, Xie Jun, Zhang Jinliang. 2004. Present situation and advance of remaining oil research technology in China[J]. Northwestern Geology, 37(4): 1-6.
[8] 刘昊,张宝雷,田冠楠. 2016. 南海海域环境条件监测数据分析[J]. 船海工程,45(5):86-90.

Liu Hao, Zhang Baolei, Tian Guannan. 2016. Analysis of the ocean environment in South China Sea area[J]. Ship & Ocean Engineering, 45(5): 86-90.
[9] 彭光荣,杜家元,冯进,等. 2022. 早—中中新世古珠江三角洲沉积格局及其控制因素[J]. 地球科学,47(11):3989-4004.

Peng Guangrong, Du Jiayuan, Feng Jin, et al. 2022. Depositional setting of ancient Pearl River Delta during Early-to-Middle Miocene: Implications for forcing factors[J]. Earth Science, 47(11): 3989-4004.
[10] 乔方利. 2012. 中国区域地质海洋学—物理海洋学[M]. 北京:海洋出版社:1-481.

Qiao Fangli. 2012. Regional geological oceano-graphy in China seas: Physical oceanography[M]. Beijing: China Ocean Press: 1-481.
[11] 孙廷彬,国殿斌,李中超,等. 2015. 鄱阳湖浅水三角洲分支河道分布特征[J]. 岩性油气藏,27(5):144-148.

Sun Tingbin, Guo Dianbin, Li Zhongchao, et al. 2015. Distribution characteristics of branch channel of shallow delta in Poyang Lake[J]. Lithologic Re-servoirs, 2015, 27(5): 144-148.
[12] 王鹏飞,霍春亮,叶小明,等. 2019. 伊拉克BU油田碳酸盐岩储层沉积过程数值模拟[J]. 油气地质与采收率,26(4):56-61.

Wang Pengfei, Huo Chunliang, Ye Xiaoming, et al. 2019. Numerical simulation of sedimentary process for carbonate reservoir in BU oilfield, Iraq[J]. Petroleum Geology and Recovery Efficiency, 26(4): 56-61.
[13] 王韬,李婷,郭文建,等. 2021. 沉积正演模拟在准噶尔盆地吉木萨尔凹陷东斜坡二叠系梧桐沟组中的应用[J]. 特种油气藏,28(1):34-41.

Wang Tao, Li Ting, Guo Wenjian, et al. 2021. Application of sedimentary forward modeling of the Permian Wutonggou Formation in the east slope of Jimusar Sag, Junggar Basin[J]. Special Oil & Gas Reservoirs, 28(1): 34-41.
[14] 魏康强,焦朝维,王振,等. 2017. 三角洲分流河道与朵叶体形成过程的物理模拟[J]. 科学技术与工程,17(23):155-160.

Wei Kang-qiang, Jiao Chaowei, Wang Zhen, et al. 2017. Physical simulation of delta distributary channel and the formation process of leaf body[J]. Science Technology and Engineering, 17(23): 155-160.
[15] 徐伟,房磊,张新叶,等. 2019. 乌干达K油田扇三角洲沉积正演模拟与应用[J]. 地球科学,44(2):513-523.

Xu Wei, Fang Lei, Zhang Xinye, et al. 2019. Sedimentary forward simulation and application of fan delta in K oil field in Uganda[J]. Earth Science, 44(2): 513-523.
[16] 杨明远,严以新,孔俊,等. 2008. 珠江口水流泥沙运动模拟研究[M]. 北京:海洋出版社:1- 183.

Yang Mingyuan, Yan Yixin, Kong Jun, et al. 2008. Simulation of flow and sediment movement in the Pearl River Estuary[M]. Beijing: China Ocean Press: 1-183.
[17] 姚章民. 2013. 珠江流域主要河流泥沙变化分析[J]. 水文,33(4):80-83.

Yao Zhangmin. 2013. Study on variation of main rivers sediment in Pearl River Basin[J]. Journal of China Hydrology, 33(4): 80-83.
[18] 张建民,王梦琪,王月杰,等. 2017. 渤海湾盆地渤中28-2南油田群鸟足状浅水三角洲识别与沉积演化[J]. 中国海洋大学学报(自然科学版),47(9):77-85.

Zhang Jianmin, Wang Mengqi, Wang Yuejie, et al. 2017. Identification and sedimentary evolution of the shallow water delta of bird-foot in Bozhong 28-2S oilfield group of Bohai Bay Basin[J]. Periodical of Ocean University of China, 47(9): 77-85.
[19] 张文彪,段太忠,刘彦锋,等. 2017. 综合沉积正演与多点地质统计模拟碳酸盐岩台地:以巴西Jupiter油田为例[J]. 石油学报,38(8):925-934.

Zhang Wenbiao, Duan Taizhong, Liu Yanfeng, et al. 2017. Integrated sedimentary forward modeling and multipoint geostatistics in carbonate platform simulation: A case study of Jupiter oilfield in Brazil[J]. Acta Petrolei Sinica, 38(8): 925-934.
[20] 张文彪,段太忠,刘彦锋,等. 2019. 定量地质建模技术应用现状与发展趋势[J]. 地质科技情报,38(3):264-275.

Zhang Wenbiao, Duan Taizhong, Liu Yanfeng, et al. 2019. Application status and development trend of quantitative geological modeling[J]. Geological Science and Technology Information, 38(3): 264-275.
[21] 张宪国,张育衡,张涛,等. 2020. 基于沉积数值模拟的辫状河心滩演化[J]. 中国石油大学学报(自然科学版),44(2):1-9.

Zhang Xianguo, Zhang Yuheng, Zhang Tao, et al. 2020. Analysis of braided bar evolution based on numerical simulation of deposition process[J]. Journal of China University of Petroleum, 44(2): 1-9.
[22] 郑胜. 2019. 准中地区三工河组浅水三角洲沉积模式及油气勘探意义[J]. 特种油气藏,26(1):87-93.

Zheng Sheng. 2019. Sedimentary pattern of the shallow-water delta in the Sangonghe Formation of central Junggar Basin and its significance for hydrocarbon exploration[J]. Special Oil & Gas Reservoirs, 26(1): 87-93.
[23] 周家伟. 2019. 古珠江三角洲沉积数值模拟及主控因素分析[D]. 杭州:浙江大学:1-92.

Zhou Jiawei. 2019. The numerical simulation and analysis of main controlling factors on paleo-Pearl River Delta sedimentary processes[D]. Hangzhou: Zhejiang University: 1-92.
[24] 朱筱敏,葛家旺,赵宏超,等. 2017. 陆架边缘三角洲研究进展及实例分析[J]. 沉积学报,35(5):945-957.

Zhu Xiaomin, Ge Jiawang, Zhao Hongchao, et al. 2017. Development of shelf-edge delta researches and typical case analyses[J]. Acta Sedimentologica Sinica, 35(5): 945-957.
[25] Allen G P, Salomon J C, Bassoullet P, et al. 1980. Effects of tides on mixing and suspended sediment transport in macrotidal estuaries[J]. Sedimentary Geology, 26(1): 69-90.
[26] Boyd R, Dalrymple R, Zaitlin B A. 1992. Classification of clastic coastal depositional environments[J]. Sedimentary Geology, 80(3): 139-150.
[27] Burpee A P, Slingerland R L, Edmonds D A, et al. 2015. Grain-size controls on the morphology and internal geometry of river-dominated deltas[J]. Journal of Sedimentary Research, 85(6): 699-714.
[28] Caldwell R L, Edmonds D A. 2014. The effects of sediment properties on deltaic processes and morphologies: A numerical modeling study[J]. Journal of Geophysical Research: Earth Surface, 119(5): 961-982.
[29] Coleman J M, Wright L D. 1975. Modern river deltas: Variability of processes and sand bodies[C]//Broussard M L. Deltas: Models for exploration. Houston: Houston Geological Society: 99-149.
[30] Dai S B, Yang S L, Cai A M. 2008. Impacts of dams on the sediment flux of the Pearl River, southern China[J]. Catena, 76(1): 36-43.
[31] Dalrymple R W, Baker E K, Harris P T, et al. 2003. Sedimentology and stratigraphy of a tide-dominated, foreland-basin delta (Fly River, Papua New Guinea)[C]//Sidi F H, Nummedal D, Imbert P, et al. Tropical deltas of Southeast Asia: Sedimentology, stratigraphy, and petroleum geology. Tulsa: SEPM: 147-173.
[32] Dalrymple R W, Choi K. 2007. Morphologic and facies trends through the fluvial-marine transition in tide-dominated depositional systems: A schematic framework for environmental and sequence-stratigraphic interpretation[J]. Earth-Science Reviews, 81(3/4): 135-174.
[33] Edmonds D A, Slingerland R L. 2010. Significant effect of sediment cohesion on delta morphology[J]. Nature Geoscience, 3(2): 105-109.
[34] Friedrichs C T, Aubrey D G. 1988. Non-linear tidal distortion in shallow well-mixed estuaries: A synthesis[J]. Estuarine, Coastal and Shelf Science, 27(5): 521-545.
[35] Galloway W E. 1975. Process framework for describing the morphologic and stratigraphic evolution of deltaic depositional systems[M]//Broussard M L. Deltas: Models for exploration. Houston: Houston Geological Society: 87-98.
[36] Geleynse N, Storms J E A, Walstra D J R, et al. 2011. Controls on river delta formation; insights from numerical modelling[J]. Earth and Planetary Science Letters, 302(1): 217-226.
[37] Gibling M R. 2006. Width and thickness of fluvial channel bodies and valley fills in the geological record: A literature compilation and classification[J]. Journal of Sedimentary Research, 76(5): 731-770.
[38] Gugliotta M, Saito Y. 2019. Matching trends in channel width, sinuosity, and depth along the fluvial to marine transition zone of tide-dominated river deltas: The need for a revision of depositional and hydraulic models[J]. Earth-Science Reviews, 191: 93-113.
[39] Gugliotta M, Saito Y, Nguyen V L, et al. 2017. 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, 147:7-26.
[40] Hoitink A J F, Wang Z B, 2017. Vermeulen B,et al. Tidal controls on river delta morphology[J]. Nature Geoscience, 10(9): 637-645.
[41] Hu K L, Ding P X, Wang Z B, et al. 2009. A 2D/3D hydrodynamic and sediment transport model for the Yangtze Estuary, China[J]. Journal of Marine Systems, 77: 114-136.
[42] Huang H S, Chen C S, Blanton J O, et al. 2008. A numerical study of tidal asymmetry in Okatee Creek, South Carolina[J]. Estuarine, Coastal and Shelf Science, 78(1): 190-202.
[43] Iwantoro A P, van der Vegt M, Kleinhans M G. 2020. Morphological evolution of bifurcations in tide-influenced deltas[J]. Earth Surface Dynamics, 2020, 8(2): 413-429.
[44] Iwantoro A P, van der Vegt M, Kleinhans M G. 2022. Stability and asymmetry of tide-influenced river bifurcations[J]. Journal of Geophysical Research: Earth Surface, 127(6): e2021JF006282.
[45] Ji X M, Zhang W. 2020. Tidal impacts on downstream hydraulic geo-metry of a tide-influenced delta[J]. Ocean Dynamics, 70(9): 1239-1252.
[46] Kolla V, Biondi P, Long B, et al. 2020. Sequence stratigraphy and architecture of the Late Pleistocene Lagniappe delta complex, northeast gulf of Mexico[J]. Geological Society, London, Special Publications, 172(1): 291-327.
[47] Kurcinka C, Dalrymple R W, Gugliotta M. 2018. Facies and architecture of river-dominated to tide-influenced mouth bars in the Lower Lajas Formation (Jurassic), Argentina[J]. AAPG Bulletin, 102(5): 885-912.
[48] Leonardi N, Canestrelli A, Sun T, et al. 2013. Effect of tides on mouth bar morphology and hydrodynamics[J]. Journal of Geophysical Research: Oceans, 118(9): 4169-4183.
[49] Lesser G R, Roelvink J A, van Kester J A T M, et al. 2004. Development and validation of a three-dimensional morphological model[J]. Coastal Engineering, 51(8): 883-915.
[50] Nienhuis J H, Hoitink A J F, Törnqvist T E. 2018. Future change to tide-influenced deltas[J]. Geophysical Research Letters, 45(8): 3499-3507.
[51] Olariu C, Bhattacharya J P. 2006. Terminal distributary channels and delta front architecture of river-dominated delta systems[J]. Journal of Sedimentary Research, 76(2): 212-233.
[52] Rossi V M, Kim W, López J L, et al. 2016. Impact of tidal currents on delta-channel deepening, stratigraphic architecture, and sediment bypass beyond the shoreline[J]. Geology, 44(11): 927-930.
[53] Rossi V M, Steel R J. 2016. The role of tidal, wave and river currents in the evolution of mixed-energy deltas: Example from the Lajas Formation (Argentina)[J]. Sedimentology, 63(4): 824-864.
[54] Sassi M G, Hoitink A J F, de Brye B, et al. 2011. Tidal impact on the division of river discharge over distributary channels in the Mahakam Delta[J]. Ocean Dynamics, 61(12): 2211-2228.
[55] Sassi M G, Hoitink A J F, de Brye B, et al. 2012. Downstream hydraulic geometry of a tidally influenced river delta[J]. Journal of Geophysical Research: Earth Surface, 117(F4): F04022.
[56] Syvitski J P M, Vörösmarty C J, Kettner A J, et al. 2005. Impact of humans on the flux of terrestrial sediment to the global coastal ocean[J]. Science, 308(5720): 376-380.
[57] van Rijn L C. 1993. Principles of sediment transport in rivers, estuaries, and coastal seas[M]. Amsterdam: Aqua Publications: 1-682.
[58] Wu C S, Ji C C, Shi B W, et al. 2019. The impact of climate change and human activities on streamflow and sediment load in the Pearl River Basin[J]. International Journal of Sediment Research, 34(4): 307-321.
[59] Xu Z H, Plink-Björklund P. 2023. Quantifying formative processes in river- and tide-dominated deltas for accurate prediction of future change[J]. Geophysical Research Letters, 50(20): 1-12.