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Yokoyama, Y. et al. Rapid glaciation and a two-stage sea level plunge into the Last Glacial Maximum. Nature 559, 603–607 (2018).
Dalrymple, RW, Leckie, DA & Tillman, RW (eds) Valleys incised in time and space. SEPM Specification. Publ. 85, 348 (2006).
Tanabe, S. et al. Holocene evolution of the Song Hong (Red River) delta system, northern Vietnam. Sediment. Geol. 187, 29–61 (2006).
Google Scholar
Busschers, FS et al. Late Pleistocene evolution of the Rhine-Meuse system in the southern North Sea basin: footprints of climate change, sea level oscillation and glacio isostasis. Fourth. Science. Tower. 26, 3216–3248 (2007).
Google Scholar
Ta, TKO et al. Last Pleistocene to Holocene stratigraphic record and evolution of the incised Paleo-Mekong valley in Vietnam. Mar. Geol. 433, 106406. https://doi.org/10.1016/j.margeo.2020.106406 (2021).
Google Scholar
Berendsen, HJA and Stouthamer, E. Paleogeographical development of the Rhine-Meuse delta, Netherlands, 268p (Koninklijke Van Gorcum, 2001).
Hijma, MP & Cohen, KM Holocene transgression of the Rhine mouth region, Netherlands/southern North Sea: paleogeography and sequence stratigraphy. sedimentology 58, 1453-1485 (2011).
Google Scholar
Wang, Z. et al. Three-dimensional evolution of the mouth of the Yangtze River, China during the Holocene: impacts of sea level, climate and human activity. Earth-Sci. Tower. 185, 938–955 (2018).
Amorosi, A. et al. Triple nature of coastal progradation during the Eustatic High Altitude of the Holocene, Po Plain, Italy – close correspondence of stratal character with distribution patterns. sedimentology 66, 3029-3052 (2019).
Google Scholar
Tanabe, S., Nakanishi, T., Ishihara, Y. & Nakashima, R. Millennial-scale stratigraphy of an incised tidal-dominated valley during the last 14 ka: spatial and quantitative reconstruction in the lowlands of Tokyo, central Japan. sedimentology 62, 1837–1872 (2015).
Google Scholar
Colman, SM et al. Radiocarbon dating, time frame, and changes in accumulation rates of Holocene estuarine sediments form the Chesapeake Bay. Fourth. Res. 57, 58–70 (2002).
Hori, K. & Saito, Y. Radiocarbon age differences between mollusc shells, plant matter, and total organic carbon: an example of Paleo-Changjiang incised valley filling in China. Fourth. Int. 455, 45–55 (2017).
Google Scholar
Fujiwara, O., Kamataki, T. & Masuda, F. Sedimentological time averaging and 14C dating of marine shells. Nucl. Instrument. Physical methods. Res. B 223–224, 540-544 (2004).
Nakanishi, T., Hong, W., Sung, KS, and Lim, J. Radiocarbon reservoir effect of shell and plant pairs in Holocene sediments around the Yeongsan River in Korea. Nucl. Instrument. Physical methods. Res. B 294, 573–578 (2013).
Nakanishi, T., Hong, W., Sung, KS, Sung, KH, and Nakashima, R. Shifts in radiocarbon ages between plants and shells from the same horizons of coastal sediments in Korea. Nucl. Instrument. Physical methods. Res. B 361, 670–679 (2015).
Weltje, GJ & von Eynatten, H. Quantitative provenance analysis of sediments: review and perspectives. Sediment. Geol. 171, 1–11 (2004).
Google Scholar
Liu, Z. et al. Source-sink transport process of river sediments in the South China Sea. Earth-Sci. Tower. 153, 238-273 (2016).
Goodbred Jr., SL & Kuehl, SA Floodplain Processes in the Bengal Basin and Ganges-Brahmaputra Sediment Storage: A Study of Accretion Using 137Cs and 210Pb geochronology. Sediment. Geol. 121, 239-258 (1998).
van der Bergh, GD, Boer, W., Schaapveld, MAS, Duc, DM and van Weering, Tj.CE Recent sedimentation and sediment accumulation rates of the Ba Lat prodelta (Red River, Vietnam). J. Asian Earth Sci. 29, 545-557 (2007).
Kuehl, SA et al. A source-to-sink perspective of the Waipaoa River margin. Earth-Sci. Tower. 153, 301–334 (2016).
Google Scholar
Shirai, M. & Hayashizaki, R. Sand grain transport process from river to deep marine regions estimated by feldspar luminescence: example from Kumano region, central Japan. island arc 22, 242-257 (2013).
Google Scholar
Dufois, F., Verney, R., Le Hir, P., Dumas, F. & Charmasson, S. Impact of winter storms on sediment erosion in the Rhône prodelta and fate of sediments in the Gulf of Lion ( Northwest Mediterranean Sea). Continent. Shelf Res. 72, 54–72 (2014).
Google Scholar
Davis, RA Jr. & Hayes, MO What is a wave-dominated coast?. Mar. Geol. 60, 313–329 (1984).
Google Scholar
Okuma, T. Influences of River Alteration and Asama Volcano Eruption in the Early Modern Period. Urban Kubota 19, 18–31 (in Japanese) (1981).
Milliman, JD & Farnsworth, KL River flow towards the coastal ocean: a global synthesis. 384p (Cambridge University Press, 2011).
Hasada, K. & Hori, K. Quantitative analysis of land transformation in a Holocene delta: an example from the Tama River Plain, central Japan. Mar. Geol. 425, 106193. https://doi.org/10.1016/j.margeo.2020.106193 (2020).
Google Scholar
Tanabe, S. Gradual accelerations in the rate of sea level rise in the region north of Tokyo Bay during the early Holocene. Fourth. Science. Tower. 248, 106575. https://doi.org/10.1016/j.quascirev.2020.106575 (2020).
Google Scholar
Tanabe, S., Nakashima, R & Ishihara, Y. Transition from a transgressive sedimentary body to a regressive river mouth body in Tokyo Bay during the early Holocene: sedimentary facies, geometry and pile-up model . Sediment. geol. 428, 106059. https://doi.org/10.1016/j.sedgeo.2021.106059 (2022).
Google Scholar
Tanabe, S. & Ishihara, Y. Formation of undulating topography and gravel beds at the base of incised valleys: examples of the Last Glacial Maximum beneath the lowlands facing Tokyo Bay. Program. Earth. Science. 8, 20. https://doi.org/10.1186/s40645-021-00411-0 (2021).
Google Scholar
van Wagoner, JC et al. An overview of the fundamentals of sequence stratigraphy and key definitions. SEPM Specification. Publ. 42, 39-45 (1988).
Google Scholar
Hori, K. & Saito, Y. A sea level jump and delta initiation in the early Holocene. Geophys. Res. Lett. 34, GL031029. https://doi.org/10.1029/2007GL031029 (2007).
Stuiver, M. & Braziunas, TF Atmospheric modeling 14C influences and 14C ages of marine specimens dating back to 10,000 BC. Radiocarbon 35, 137-189 (1993).
Yoshida, K. et al. Pre-bomb age of marine tanks in the Western Pacific. Radiocarbon 52, 1197-1206 (2010).
Google Scholar
Kondo, Y. Burial depth of infaunal bivalves: observation of living species and its relationship to shell morphology. Trans. proc. Paleont. Soc. Japan 148, 306–323 (1987).
Google Scholar
Okutani, T. Marine molluscs in Japan. 1173p (in Japanese) (Tokai Univ. Press, 2000).
Shishikura, M. History of paleoseismos along the Sagami Trough, central Japan: a review of coastal paleoseismological studies in the Kanto region. Episodes 37, 246-257 (2014).
Google Scholar
Bhattacharya, JP Deltas in Facies Models 4 (eds. Dalrymple, RG & James, NP), 233–264 (Geological Association of Canada, 2010).
Matsumoto, E. The sedimentary environment in Tokyo Bay. Chikyukagaku (Geochemistry) 17, 27–32 (in Japanese with English summary) (1982)
Komatsubara, J., Ishihara, Y., Nakashima, R. & Uchida, M. Difference in the timing of maximum flooding in two adjacent lowlands of the Tokyo area caused by the difference in sediment supply rate. Fourth. Int. 455, 56–69 (2017).
Google Scholar
Kazaoka, O. et al. Alluvia and artificial soils in Explanatory text of the urban geological map of the northern area of Chiba prefecture. https://gbank.gsj.jp/urbangeol/data/explanatory/Chiba/GSJ_DBS_URG_Explanatory_Chapter5_20181107.pdf (in Japanese) (2018).
Komatsubara, J. Nakayama, T. & Nakazawa, T. Stratigraphy of Late Postglacial Pleistocene to Holocene Deposits Beneath the Wakasu Region, Koto-ku, Tokyo, Central Japan: Sedimentary Facies and Core Deposition Ages GS- KWS-1. J. Sediment. Soc. Japan 79, 3–14 (in Japanese with English summary) (2020).
Yoneda, M. et al. ADM 14C measurements and preparatory techniques at NIES-TERRA. Nucl. Instrument. Physical methods. Res. B 223–224, 116-123 (2004).
Saito-Kokubu, Y. et al. Current status of the AMS facility at the Tono Geoscience Center of the Japan Atomic Energy Agency. Nucl. Instrument. Physical methods. Res. B 294, 43–45 (2013).
Stuiver, M., Reimer, PJ & Reimer, RW CALIB 7.1. http://calib.org/calib/ (2020).
Reimer, PJ et al. IntCal13 and Marine13 radiocarbon age calibration curves 0–50,000 cal years BP. Radiocarbon 55, 1869-1887 (2013).
