[1] 蔡东亿,阎希柱. 2014. 盐度对双齿围沙蚕耗氧率和排氨率的影响[J]. 海洋科学,38(5):54-59.

Cai Dongyi, Yan Xizhu. 2014. Effects of salinity on oxygen consumption rate and ammonia-N excretion rate of Perinereis aibuhitensis [J]. Marine Sciences, 38(5): 54-59.
[2] 韩万兵. 2017. 总有机碳分析仪测定土壤中的有机碳[J]. 煤炭与化工,40(9):72-74.

Han Wanbing. 2017. Determination of organic carbon in soil by total organic carbon analyzer[J]. Coal and Chemical Industry, 40(9): 72-74.
[3] 胡斌,王冠忠,齐永安. 1997. 痕迹学理论与应用[M]. 徐州:中国矿业大学出版社: 41-50.

Hu Bin, Wang Guanzhong, Qi Yong'an. 1997. Theory and application of ichnology[M]. Xuzhou: China University of Mining and Technology Press: 41-50.
[4] 胡斌,张白梅,王海邻,等. 2015. 现代滦河三角洲沉积中的生物遗迹[J]. 河南理工大学学报(自然科学版),34(2):185-191.

Hu Bin, Zhang Baimei, Wang Hailin, et al. 2015. Neoichnology in modern Luanhe Delta deposits[J]. Journal of Henan Polytechnic University (Natural Science), 34(2): 185-191.
[5] 胡海英,黄国如. 2011. 珠江三角洲潮位时间序列的混沌特性分析[J]. 水电能源科学,29(6):21-23.

Hu Haiying, Huang Guoru. 2011. Analysis of chaotic characteristics of tide level series in Pearl River Delta[J]. Water Resources and Power, 29(6): 21-23.
[6] 王翠,王媛媛,胡斌. 2023. 黄河三角洲潮坪环境现代生物遗迹与物化条件的响应关系[J]. 沉积学报,41(3):748-762.

Wang Cui, Wang Yuanyuan, Hu Bin. 2023. The response relationship between biogenic structures and physicochemical stresses of the Yellow River Deltaic tidal flat[J]. Acta Sedimentologica Sinica, 41(3): 748-762.
[7] 王海邻. 2018. 我国东部沿海潮坪沉积中的现代生物遗迹研究[D]. 焦作:河南理工大学:49-52.

Wang Hailin. 2018. Studies about the modern biogenic traces in the tidal flat deposits along the coastal zones of eastern China[D]. Jiaozuo: Henan Polytechnic University: 49-52.
[8] 王海邻,张彬,宋慧波,等. 2022. 滦河三角洲潮坪环境现代生物遗迹组合及其分布特征[J]. 古地理学报,24(6):1179-1192.

Wang Hailin, Zhang Bin, Song Huibo, et al. 2022. Assemblages of lebensspuren and distribution characteristics in tidal flat of Luanhe Delta[J]. Journal of Palaeogeography, 24(6): 1179-1192.
[9] 王珊珊. 2008. 珠江三角洲和近岸河口海域现代沉积环境及晚更新世以来的环境演变[D]. 青岛:中国海洋大学: 11-13.

Wang Shanshan. 2008. Present sedimentary environments and environment evolvement since Late Pleistocene for the Pearl River Delta and intracoastal estuary and sea area[D]. Qingdao: Ocean University of China: 11-13.
[10] 王媛媛,勾松林,张国成. 2024. 现代珠江三角洲前缘生物遗迹组成与分布特征[J]. 沉积学报,42(5):1512-1529.

Wang Yuanyuan, Gou Songlin, Zhang Guocheng. 2024. Composition and distribution characteristics of biological traces in the Pearl River Delta front[J]. Acta Sedimentologica Sinica, 42(5): 1512-1529.
[11] 王媛媛,王学芹,胡斌. 2019. 黄河三角洲潮坪环境中现代生物遗迹组成与分布特征[J]. 沉积学报,37(6):1244-1257.

Wang Yuanyuan, Wang Xueqin, Hu Bin. 2019. The composition and distribution characteristics of biogenic sedimentary structures in tidal flat of Yellow River Delta[J]. Acta Sedimentologica Sinica, 37(6): 1244-1257.
[12] 吴贤涛. 1986. 痕迹学入门[M]. 北京:煤炭工业出版社: 1-11.

Wu Xiantao. 1986. The basic of ichnology[M]. Beijing: China Coal Industry Publishing House: 1-11.
[13] 张白梅. 2014. 滦河三角洲现代生物遗迹的组成与分布特征[D]. 焦作:河南理工大学: 34-37.

Zhang Baimei. 2014. The biogenic sedimentary structures of the Luanhe River Delta and their composition and distribution characters[D]. Jiaozuo: Henan Polytechnic University: 34-37.
[14] 赵焕庭. 1989. 珠江河口的水文和泥沙特征[J]. 热带地理,9(3):201-212.

Zhao Huanting. 1989. Hydrological and sedimentary characteristics of the Pearl River estuary[J]. Tropical Geography, 9(3): 201-212.
[15] 郑伟,孙长彦,白万备,等. 2015. 洛阳龙门地区寒武系第三统张夏组碳酸盐岩风暴沉积类型及遗迹化石特征[J]. 地质科技情报,34(6):92-99.

Zheng Wei, Sun Changyan, Bai Wanbei, et al. 2015. Types of storm deposit sequence of carbonates and characteristics of trace fossils in Zhangxia Formation of 3rd epoch of carbonates in Longmen, Luoyang region[J]. Geological Science and Technology Information, 34(6): 92-99.
[16] 钟子悦,余明辉,陈小齐,等. 2023. 珠江三角洲河网地形和径流条件变化对潮动力格局的影响[J]. 水资源保护,39(3):213-221.

Zhong Ziyue, Yu Minghui, Chen Xiaoqi, et al. 2023. Effects of changes in river network topography and runoff on tidal dynamic pattern in Pearl River Delta[J]. Water Resources Protection, 39(3): 213-221.
[17] 周青伟,马道修,徐明广,等. 1987. X射线照像在珠江三角洲现代沉积环境调查中的应用及其意义[J]. 海洋地质与第四纪地质,7(3):79-89.

Zhou Qingwei, Ma Daoxiu, Xu Mingguang, et al. 1987. Application of X-ray radiography in modern sedimentary environmental investigations in the Zhujiang River Delta and its significance[J]. Marine Geology & Quaternary Geology, 7(3): 79-89.
[18] 周瑛,刘洁,吴仁海. 2003. 珠江三角洲水环境问题及其原因分析[J]. 云南地理环境研究,15(4):47-53.

Zhou Ying, Liu Jie, Wu Renhai. 2003. Analysis on water environmental problems and their causes in Pearl River Delta[J]. Yunnan Geographic Environment Research, 15(4): 47-53.
[19] Ali S, Wilson B. 2021. Ichnology of the Pliocene Casa Cruz member (Moruga Formation), Trinidad, West Indies: Delineating depositional environments and environmental stresses[J]. Journal of South American Earth Sciences, 112: 103584.
[20] Ayranci K, Dashtgard S E. 2013. Infaunal holothurian distributions and their traces in the Fraser River delta front and prodelta, British Columbia, Canada[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 392: 232-246.
[21] Ayranci K, Dashtgard S E. 2016. Asymmetrical deltas below wave base: Insights from the Fraser River Delta, Canada[J]. Sedimentology, 63(3): 761-779.
[22] Ayranci K, Dashtgard S E, MacEachern J A. 2014. A quantitative assessment of the neoichnology and biology of a delta front and prodelta, and implications for Delta ichnology[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 409: 114-134.
[23] Biranvand B, Sharafi M, Fursich F T, et al. 2024. Taphonomic analysis of shell concentrations in deltaic Miocene deposits of the South Caspian Basin, eastern Paratethys[J]. Historical Biology, 36(11): 2485-2501.
[24] Crippa G, Baucon A, Felletti F, et al. 2018. A multidisciplinary study of ecosystem evolution through Early Pleistocene climate change from the marine Arda River section, Italy[J]. Quaternary Research, 89(2): 533-562.
[25] Dashtgard S E. 2011a. Neoichnology of the lower delta plain: Fraser River Delta, British Columbia, Canada: Implications for the ichnology of deltas[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 307(1/2/3/4): 98-108.
[26] Dashtgard S E. 2011b. Linking invertebrate burrow distributions (neoichnology) to physicochemical stresses on a sandy tidal flat: Implications for the rock record[J]. Sedimentology, 58(6): 1303-1325.
[27] Kulkarni K G, Panchang R. 2015. New insights into polychaete traces and fecal pellets: another complex ichnotaxon? [J]. PLOS ONE, 10(10): e0139933.
[28] MacEachern J A, Bann K L, Pemberton S G, et al. 2007. The ichnofacies paradigm: High resolution paleoenvironmental interpretation of the rock record[J]. SEPM Short Course Notes, 52: 27-64.
[29] Morelle C, Denayer J. 2020. First description of the ichnofauna from the type locality of the Famennian stage (Late Devonian) of S Belgium[J]. Ichnos, 27(4): 384-405.
[30] Mørk A, Bromley R G. 2008. Ichnology of a marine regressive systems tract: The Middle Triassic of Svalbard[J]. Polar Research, 27(3): 339-359.
[31] Patel S J, Desai B G. 2009. Animal-sediment relationship of the crustaceans and polychaetes in the intertidal zone around Mandvi, Gulf of Kachchh, western India[J]. Journal of the Geological Society of India, 74(2): 233-259.
[32] Paz D M, Richiano S, Varela A N, et al. 2020. Ichnological signatures from wave- and fluvial-dominated deltas: The La Anita Formation, Upper Cretaceous, Austral-Magallanes Basin, Patagonia[J]. Marine and Petroleum Geology, 114: 104168.
[33] Pickerill R K. 1992. Carboniferous nonmarine invertebrate ichnocoenoses from southern New Brunswick, eastern Canada[J]. Ichnos, 2(1): 21-35.
[34] Pieńkowski G, Uchman A, Ninard K, et al. 2021. Ichnology, sedimentology, and orbital cycles in the hemipelagic Early Jurassic Laurasian Seaway (Pliensbachian, Cardigan Bay Basin, UK)[J]. Global and Planetary Change, 207: 103648.
[35] Rodríguez-Tovar F J, van Dijk G, Maars J, et al. 2023. Ichnological analysis of the Messinian-Zanclean (Miocene-Pliocene) transition at Eraclea Minoa (Sicily): Tracemaker response to the Terminal Messinian flood[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 619: 111539.
[36] Schlirf M, Uchman A. 2005. Revision of the ichnogenus Sabellarifex Richter, 1921 and its relationship to Skolithos Haldeman, 1840 and Polykladichnus Fürsich, 1981[J]. Journal of Systematic Palaeontology, 3(2): 115-131.
[37] Singh M C, Kundal P, Kushwaha R A S, et al. 2010. Ichnology of Bhuban and Boka Bil Formations, Oligocene-Miocene deposits of Manipur Western Hill, northeast India[J]. Journal of the Geological Society of India, 76(6): 573-586.
[38] Tiwari R P, Rajkonwar C, Lalchawimawii, et al. 2011. Trace fossils from Bhuban Formation, Surma Group (Lower to Middle Miocene) of Mizoram India and their palaeoenvironmental significance[J]. Journal of Earth System Science, 120(6): 1127-1143.
[39] van Wagoner J C, Bertram G T. 1995. Sequence stratigraphy of foreland basin deposits: Outcrop and subsurface examples from the Cretaceous of North America[M]. Tulsa: American Association of Petroleum Geologists: 487.
[40] Virtasalo J J, Bonsdorff E, Moros M, et al. 2011. Ichnological trends along an open-water transect across a large marginal-marine epicontinental basin, the modern Baltic Sea[J]. Sedimentary Geology, 241(1/2/3/4): 40-51.
[41] Wang Y Y, Wang X Q, Hu B, et al. 2019a. Tomographic reconstructions of crab burrows from deltaic tidal flat: Contribution to palaeoecology of decapod trace fossils in coastal settings[J]. Palaeoworld, 28(4): 514-524.
[42] Wang Y Y, Wang X Q, Uchman A, et al. 2019b. Burrows of the polychaete Perinereis aibuhiutensis on a tidal flat of the Yellow River Delta in China: Implications for the ichnofossils Polykladichnus and Archaeonassa [J]. Palaios, 34(5): 271-279.
[43] Wood J D, Bodin S, Redfern J, et al. 2014. Controls on facies evolution in low accommodation, continental-scale fluvio-paralic systems (Messak Fm, SW Libya)[J]. Sedimentary Geology, 303: 49-69.
[44] Zhang Q, Chen Y D, Jiang T, et al. 2011. Human-induced regulations of river channels and implications for hydrological alterations in the Pearl River Delta, China[J]. Stochastic Environmental Research and Risk Assessment, 25(7): 1001-1011.
[45] Zhang Q, Xu C Y, Chen X H, et al. 2012. Abrupt changes in the discharge and sediment load of the Pearl River, China[J]. Hydrological Processes, 26(10): 1495-1508.