Abstract
The Nakdong River delta, located in southeastern Korea, preserves thick and wide sediments, which are suitable for the high-resolution study of the evolution of depositional environments in the lower delta plain area. This study traces the Holocene evolution of the Nakdong River delta using deep drill core (ND-3; 46.60 m thick) sediments from the present delta plain. Sedimentary units of the sediments were classified based on grain size compositions and sedimentary structures: (A) alluvial zone, (B) estuarine zone, (C) shallow marine, (D) prodelta, (E) delta front, and (F) delta plain. The weathered sediment, paleosol, was observed at 43.16 m below the surface. There is an unconformity (43.10 m) to separate a Pleistocene sediment layer in the lowermost part differentiating from a Holocene sediment layer in the upper part of the core. The shallow marine sedimentary unit (32.20~23.50 m), in which grain size decreases upward is overlain by the prodelta unit (23.50~15.10 m), which consists of fine-grained sediments and relatively homogeneous sedimentary facies. The boundary between the delta front unit (15.10~8.00 m) and the delta plain unit (8.00~0.00 m) appears to lie at 8.0 m, and the variation in grain size is different; coarsening upward in the delta front unit and fining upward in the delta front unit, respectively. These sediments are characterized by a lot of sand–mud couplets and mica flakes aligned along with cross-stratification, which may be deposited in relatively high-energy environments. Until 13 cal ka BP, the sea level was 70 m below the present level and the drilling site might be located onshore. At 10 cal ka BP, the sea level was located 50 m below the present level and the drilling site might be moved to an estuarine environment. From 8 to 6 cal ka BP, a transgression phase occurred as a result of coastline invasion by the rapid rise of the sea level. Thus, the drilling site was drowned in a shallow marine environment. After 6 cal ka BP, the sea level reached the present level, and, since then, progradation might begin to form, primarily by more sediment input. After this period, the progradation phase continues as the sediments have advanced and the delta grows.
Highlights
To investigate the patterns of sedimentary evolution in the Nakdong River delta related to Holocene sea-level change, we analyzed the sedimentary facies, grain size, and ages of ND-3 drill core sediments, and interpreted the sedimentary environment at each stage
Pleistocene paleosol in the lowermost core sediments and migrating into the Holocene sediments characterized by shallow marine, prodelta, delta front, and the delta plain deposits toward the upper part of the core sediments
For the study of different sediment distribution among the Nakdong River delta cores, we compared the ND-3 sediments with KND-3, and ND-2 core sediments, which are located at the same elevation as the ND-3 core sediments
Summary
Sea-level change, sediment supply, and accommodation are three major factors of river delta evolution [1]. As the sea level has risen since the Last Glacial Maximum (LGM), the accommodation space of the coastal area has increased. During the last 7–6 ka years, where sea level has been stable or slightly fallen in stages, the sediment discharge from the land to the ocean has increased and many river deltas have been formed [2,3]. Deltas have become the most important depocenter of the Holocene, and many delta evolution studies have been conducted in the world. Asian deltaic sediments can provide highresolution information about the paleoenvironmental evolution because they are supplied
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