[1] Wilson J L. Carbonate facies in geologic history[M]. New York: Springer, 1975: 1-475.
[2] Tucker M E, Wright V P. Carbonate sedimentology[M]. Oxford: Blackwell Science Ltd, 1990: 1-482.
[3] Flügel E. Microfacies of carbonate rocks[M]. Berlin: Springer, 2004: 1-976.
[4]

Ma Y S, Guo X S, Guo T L, et al. The Puguang gas field: New giant discovery in the mature Sichuan Basin, southwest China[J]. AAPG Bulletin, 2007, 91(5): 627-643.
[5] 陈娅娜,张建勇,李文正,等. 四川盆地寒武系龙王庙组岩相古地理特征及储层成因与分布[J]. 海相油气地质,2020,25(2):171-180.

Chen Yana, Zhang Jianyong, Li Wenzheng, et al. Lithofacies paleogeography, reservoir origin and distribution of the Cambrian Longwangmiao Formation in Sichuan Basin[J]. Marine Origin Petroleum Geology, 2020, 25(2): 171-180.
[6] 周进高,房超,季汉成,等. 四川盆地下寒武统龙王庙组颗粒滩发育规律[J]. 天然气工业,2014,34(8):27-36.

Zhou Jingao, Fang Chao, Ji Hancheng, et al. A development rule of Lower Cambrian Longwangmiao grain beaches in the Sichuan Basin[J]. Natural Gas Industry, 2014, 34(8): 27-36.
[7] 杨威,魏国齐,谢武仁, 等. 四川盆地下寒武统龙王庙组沉积模式新认识[J]. 天然气工业,2018,38(7):8-15.

Yang Wei, Wei Guoqi, Xie Wuren, et al. New understandings of the sedimentation mode of Lower Cambrian Longwangmiao Fm reservoirs in the Sichuan Basin[J]. Natural Gas Industry, 2018, 38(7): 8-15.
[8] 胡明毅,孙春燕,高达. 塔里木盆地下寒武统肖尔布拉克组构造—岩相古地理特征[J]. 石油与天然气地质,2019,40(1):12-23.

Hu Mingyi, Sun Chunyan, Gao Da. Characteristics of tectonic-lithofacies paleogeography in the Lower Cambrian Xiaoerbulake Formation, Tarim Basin[J]. Oil Gas Geology, 2019, 40(1): 12-23.
[9] Handford C R, Loucks R G. Carbonate depositional sequences and systems tracts-responses of carbonate platforms to relative sea-level changes[M]//Loucks R G, Sarg J F. Carbonate sequence stratigraphy: Recent developments and applications. Tulsa: AAPG, 1993: 3-42.
[10] Jones B, Desrochers A. Shallow platform carbonates[M]//Walker R G, James N P. Facies models, response to sea level change. St. Johns: Geological Association of Canada, 1992: 277-301.
[11] Jones B. Warm-water neritic carbonates[M]//James N P, Dalrymple R W. Facies models 4. St. Johns: Geological Association of Canada, 2010: 341-369.
[12] Pratt B, James N P, Cowan C A. Peritidal carbonates[M]//Walker R G, James N P. Facies models: Response to sea level change. St. Johns: Geological Association of Canada, 1992: 303-322.
[13] Pratt B R. Peritidal carbonates[M]//James N P, Dalrymple R W. Facies models 4. St. Johns: Geological Association of Canada, 2010: 401-420.
[14] James N P. Shallowing-upwards sequences in carbonates[M]//Walker R G. Facies models. 2nd ed. St. Johns: Geological Association of Canada, 1984: 213-228.
[15] James N P, Jones B. Origin of carbonate sedimentary rocks[M]. Chichester: John Wiley Sons, Inc, 2016: 1-446.
[16] Purser B H, Evans G. Regional sedimentation along the Trucial Coast, SE Persian Gulf[M]//Purser B H. The Persian Gulf: Holocene carbonate sedimentation and diagenesis in a shallow Epicontinental Sea. Berlin: Springer, 1973: 211-231.
[17]

Markello J R, Read J F. Upper Cambrian intrashelf basin, Nolichucky Formation, southwest Virginia Appalachians[J]. AAPG Bulletin, 1982, 66(7): 860-878.
[18] Shaw A B. Time in stratigraphy[M]. New York: McGraw-Hill, 1964: 1-365.
[19]

Irwin M L. General theory of epeiric clear water sedimentation[J]. AAPG Bulletin, 1965, 49(4): 445-459.
[20]

Pratt B R, James N P. The St George Group (Lower Ordovician) of western Newfoundland: Tidal flat island model for carbonate sedimentation in shallow epeiric seas[J]. Sedimentology, 1986, 33(3): 313-343.
[21]

Cram J M. The influence of continental shelf width on tidal range: Paleoceanographic implications[J]. The Journal of Geology, 1979, 87(4): 441-447.
[22]

Slingerland R. Numerical computation of co-oscillating palaeotides in the Catskill epeiric sea of eastern north America[J]. Sedimentology, 1986, 33(4): 487-497.
[23] James N P, Stevens R K, Barnes C R, et al. Evolution of a Lower Paleozoic continental-margin carbonate platform, northern Canadian Appalachians[M]//Crevello P D, Wilson J L, Sarg J F, et al. Controls on carbonate platforms and basin development. Tulsa: SEPM Society for Sedimentary Geology, 1989: 123-165.
[24] Manfrino C, Ginsburg R N. Pliocene to Pleistocene depositional history of the upper platform margin[M]//Ginsburg R N. Subsurface geology of a prograding carbonate platform margin, great Bahama Bank: Results of the Bahamas drilling project. Tulsa: SEPM Society for Sedimentary Geology, 2001, 70: 17-39.
[25]

Eberli G P, Ginsburg R N. Segmentation and coalescence of Cenozoic carbonate platforms, northwestern Great Bahama Bank[J]. Geology, 1987, 15(1): 75-79.
[26] Eberli G P, Ginsburg R N. Cenozoic progradation of northwestern Great Bahama Bank, a record of lateral platform growth and sea-level fluctuations[M]//Crevello P D, Wilson J L, Sarg J F, et al. Controls on carbonate platforms and basin development. Tulsa: SEPM Society for Sedimentary Geology, 1989: 339-351.
[27]

Masaferro J L, Eberli G P. Jurassic-Cenozoic structural evolution of the southern Great Bahama Bank[J]. Sedimentary Basins of the World, 1999, 4: 167-193.
[28]

Purdy E G. Recent Calcium carbonate facies of the Great Bahama Bank. 2. Sedimentary facies[J]. The Journal of Geology, 1963, 71(4): 472-497.
[29] Reijmer J J G, Swart P K, Bauch T, et al. A Re-evaluation of facies on Great Bahama Bank I: New facies maps of western Great Bahama Bank[M]//Swart P K, Eberli G P, McKenzie J A, et al. Perspectives in carbonate geology: A tribute to the career of Robert Nathan Ginsburg. Chichester: IAS, 2009: 29-46.
[30] Shinn E A. Tidal flat environment[M]//Scholle P A, Bebout D G, Moore C H. Carbonate depositional environments. Tulsa: AAPG, 1983: 171-210.
[31]

Hardie L A, Shinn E A. Carbonate depositional environments, modern and ancient part 3: Tidal flats[J]. Colorado School of Mines Quarterly, 1986, 81: 1-74.
[32]

Maloof A C, Grotzinger J P. The Holocene shallowing-upward parasequence of north-west Andros Island, Bahamas[J]. Sedimentology, 2012, 59(4): 1375-1407.
[33]

Wu M Y, Harris P, Eberli G, et al. Sea-level, storms, and sedimentation-controls on the architecture of the Andros tidal flats (Great Bahama Bank)[J]. Sedimentary Geology, 2021, 420: 105932.
[34]

Wright V P. Peritidal carbonate facies models: A review[J]. Geological Journal, 1984, 19(4): 309-325.
[35]

Rankey E C, Reeder S L. Controls on platform-scale patterns of surface sediments, shallow Holocene platforms, Bahamas[J]. Sedimentology, 2010, 57(6): 1545-1565.
[36]

Rankey E C, Reeder S L. Holocene oolitic marine sand complexes of the Bahamas[J]. Journal of Sedimentary Research, 2011, 81(2): 97-117.
[37] Maxwell W G H. Atlas of the great barrier reef[M]. Amsterdam: Elsevier, 1968: 1-258.
[38] Davies P J, Symonds P A, Feary D A, et al. The evolution of the carbonate platforms of northeast Australia[M]//Crevello P D, Wilson J L, Sarg J F, et al. Controls on carbonate platforms and basin development. Tulsa: SEPM Society for Sedimentary Geology, 1989: 233-258.
[39] Davies P J. Great barrier reef: Origin, evolution, and modern development[M]//Hopley D. Encyclopedia of modern coral reefs: Structure, form and process. Dordrecht: Springer, 2011: 504-534.
[40] Purser B H. The Persian Gulf: Holocene carbonate sedimentation and diagenesis in a shallow epicontinental sea[M]. Berlin: Springer, 1973: 1-471.
[41]

Dravis J J, Wanless H R. Impact of strong easterly trade winds on carbonate petroleum exploration-relationships developed from Caicos Platform, southeastern Bahamas[J]. Marine and Petroleum Geology, 2017, 85: 272-300.
[42]

van Hengstum P J, Donnelly J P, Toomey M R, et al. Heightened hurricane activity on the Little Bahama Bank from 1350 to 1650 AD[J]. Continental Shelf Research, 2014, 86: 103-115.
[43]

Carter R M, Larcombe P, Dye J E, et al. Long-shelf sediment transport and storm-bed formation by Cyclone Winifred, central Great Barrier Reef, Australia[J]. Marine Geology, 2009, 267(3/4): 101-113.
[44]

Keen T R, Bentley S J, Vaughan W C, et al. The generation and preservation of multiple hurricane beds in the northern Gulf of Mexico[J]. Marine Geology, 2004, 210(1/2/3/4): 79-105.
[45]

Martin T, Muller J. The geologic record of Hurricane Irma in a southwest Florida back-barrier lagoon[J]. Marine Geology, 2021, 441: 106635.
[46] 何登发,贾承造,李德生,等. 塔里木多旋回叠合盆地的形成与演化[J]. 石油与天然气地质,2005,26(1):64-77.

He Dengfa, Jia Chengzao, Li Desheng, et al. Formation and evolution of polycyclic superimposed Tarim Basin[J]. Oil Gas Geology, 2005, 26(1): 64-77.
[47]

Guo C, Chen D Z, Zhou X Q, et al. Depositional facies and cyclic patterns in a subtidal-dominated ramp during the Early-Middle Ordovician in the western Tarim Basin (NW China)[J]. Facies, 2018, 64(3): 16.
[48]

Dumas S, Arnott R W C. Origin of hummocky and swaley cross-stratification- the controlling influence of unidirectional current strength and aggradation rate[J]. Geology, 2006, 34(12): 1073-1076.
[49]

Grundvåg S A, Jelby M E, Olaussen S, et al. The role of shelf morphology on storm-bed variability and stratigraphic architecture, Lower Cretaceous, Svalbard[J]. Sedimentology, 2021, 68(1): 196-237.
[50]

Sami T, Desrochers A. Episodic sedimentation on an Early Silurian, storm‐dominated carbonate ramp, Becscie and Merrimack formations, Anticosti Island, Canada[J]. Sedimentology, 1992, 39(3): 355-381.
[51]

Waters B B, Spencer R J, Demicco R V. Three-dimensional architecture of shallowing-upward carbonate cycles: Middle and upper Cambrian Waterfowl Formation, Canmore, Alberta[J]. Bulletin of Canadian Petroleum Geology, 1989, 37(2): 198-209.
[52]

Koerschner W F, Read J F. Field and modelling studies of Cambrian carbonate cycles, Virginia, Appalachians[J]. Journal of Sedimentary Research, 1989, 59(5): 654-687.
[53]

Cloyd K C, Demicco R V, Spencer R J. Tidal channel, levee, and crevasse-splay deposits from a Cambrian tidal channel system: A new mechanism to produce shallowing-upward sequences[J]. Journal of Sedimentary Research, 1990, 60(1): 73-83.
[54]

Zhang Y Q, Chen D Z, Zhou X Q, et al. Depositional facies and stratal cyclicity of dolomites in the Lower Qiulitag Group (upper Cambrian) in northwestern Tarim Basin, NW China[J]. Facies, 2015, 61(1): 417.
[55]

Guo C, Chen D Z, Song Y F, et al. Depositional environments and cyclicity of the Early Ordovician carbonate ramp in the western Tarim Basin (NW China)[J]. Journal of Asian Earth Sciences, 2018, 158: 29-48.
[56]

Ding Y, Chen D Z, Zhou X Q, et al. Cavity-filling dolomite speleothems and submarine cements in the Ediacaran Dengying microbialites, South China: Responses to high-frequency sea-level fluctuations in an ‘aragonite-dolomite sea’[J]. Sedimentology, 2019, 66(6): 2511-2537.
[57]

Han J, Chen D Z, Cao Z C, et al. Facies analysis and depositional evolution of Lower-Middle Ordovician carbonates in the Shuntuoguole Low Uplift of Tarim Basin (NW China)[J]. Facies, 2024, 70(1): 2.
[58]

Aitken J D. Classification and environmental significance of cryptalgal limestones and dolomites, with illustrations from the Cambrian and Ordovician of southwestern Alberta[J]. Journal of Sedimentary Research, 1967, 37(4): 1163-1178.
[59]

Riding R. Microbial carbonates: The geological record of calcified bacterial-algal mats and biofilms[J]. Sedimentology, 2000, 47(Suppl.1): 179-214.
[60]

Chen D Z, Yang B, Song Y F, et al. Depositional facies and evolution of sponge-microbial-constructed carbonate platforms in the Lower Cambrian (Stage 3), Tarim Basin, China: Understanding from anatomy[J]. Marine and Petroleum Geology, 2024, 167: 106957.
[61]

Chafetz H S. Marine peloids: A product of bacterially induced precipitation of calcite[J]. Journal of Sedimentary Research, 1986, 56(6): 812-817.
[62]

Adachi N, Ezaki Y, Liu J B. The fabrics and origins of peloids immediately after the end-Permian extinction, Guizhou province, South China[J]. Sedimentary Geology, 2004, 164(1/2): 161-178.
[63] 沙庆安,江茂生. 鲕粒滩相与藻坪相沉积:鲁西地区中寒武统张夏组剖析[J]. 沉积学报,1998,16(4):62-70.

Sha Qing’an, Jiang Maosheng. The deposits of oolitic shoal facies and algal flat facies: Dissect of the Zhangxia Formation of the Middle Cambrian, western Shandong province[J]. Acta Sedimentologica Sinica, 1998, 16(4): 62-70.
[64] 沙庆安. 关于滩相沉积[J]. 古地理学报,1999,1(3):8-12.

Sha Qing’an. Study on shoal facies deposit[J]. Journal of Palaeogeography, 1999, 1(3): 8-12.