Abstract
Microbial interaction with minerals are significantly linked with depositional conditions during glacial and interglacial periods, providing a unique redox condition in the sedimentary process. Abiotic geophysical and geochemical properties, including sedimentary facies, magnetic susceptibility, grain size, clay mineralogy, and distribution of elemental compositions in the sediments, have been widely used to understand paleo-depositional environments. In this study, microbial abundance and diversity in the core sediments (6.7 m long) from the northeastern slope of Dokdo Island were adapted to characterize the conventionally defined sedimentary depositional units and conditions in light of microbial habitats. The units of interglacial (Unit 1, <11.5 ka) and late glacial (Unit 2, 11.5–14.5 ka) periods in contrast to the glacial period (Unit 3, >14.5 ka) were distinctively identified in the core, showing a sharp boundary marked by the laminated Mn-carbonate (CaM) mud between bioturbated (Unit 1 and 2) and laminated mud (Unit 3). Based on the marker beds and the occurrence of sedimentary facies, core sediments were divided into three units, Unit 1 (<11.5 ka, interglacial), Unit 2 (11.5–14.5 ka, late glacial), and Unit 3 (>14.5 ka, glacial), in descending order. The sedimentation rate (0.073 cm/year), which was three times higher than the average value for the East Sea (Sea of Japan) was measured in the late glacial period (Unit 2), indicating the settlement of suspended sediments from volcanic clay in the East Sea (Sea of Japan), including Doldo Island. The Fe and Mg-rich smectite groups in Unit 2 can be transported from volcanic sediments, such as from the volcanic island in the East Sea or the east side of Korea, while the significant appearance of the Al-rich smectite group in Unit 1 was likely transported from East China by the Tsushima Warm Current (TWC). The appearance of CaM indicates a redox condition in the sedimentary process because the formation of CaM is associated with an oxidation of Mn2+ forming Mn-oxide in the ocean, and a subsequent reduction of Mn-oxide occurred, likely due to Mn-reducing bacteria resulting in the local supersaturation of Mn2+ and the precipitation of CaM. The low sea level (−120 m) in the glacial period (Unit 3) may restrict water circulation, causing anoxic conditions compared to the late glacial period (Unit 2), inducing favorable redox conditions for the formation of CaM in the boundary of the two units. Indeed, Planctomycetaceae, including anaerobic ammonium oxidation (ANAMMOX) bacteria capable of oxidizing ammonium coupled with Mn-reduction, was identified in the CaM layer by Next Generation Sequencing (NGS). Furthermore, the appearance of aerobic bacteria, such as Alphaproteobacteria, Gammaproteobacteria, and Methylophaga, tightly coupled with the abundance of phytoplankton was significantly identified in Unit 1, suggesting open marine condition in the interglacial period. Bacterial species for each unit displayed a unique grouping in the phylogenetic tree, indicating the different paleo-depositional environments favorable for the microbial habitats during the glacial and interglacial periods.
Highlights
The characteristics of lithostratigraphy in the sediments, accompanied by magnetic susceptibility, grain size distribution, clay composition, and chemical analyses of pore water, have been widely used to determine the paleo-depositional environments of seafloor sediments
The appearance of marker beds, including U-Oki tephra (154–155.5 cm; 9.3 ka), the TL-1 layer (186–188 cm; 11.5 ka), and CaM (476–480 cm; 14.5 ka), reflecting the geological time scale in the East Sea strongly supports the characteristics of sedimentary facies for the interglacial and last glacial periods [42]
The characteristics of sedimentary facies associated with changes in depositional conditions during the glacial and the interglacial periods are likely linked with microbial habitats
Summary
The characteristics of lithostratigraphy in the sediments, accompanied by magnetic susceptibility, grain size distribution, clay composition, and chemical analyses of pore water, have been widely used to determine the paleo-depositional environments of seafloor sediments. Distinctive marker beds, such as a tephra layer and specific-colored layer often found in the core sediments, are useful in determining sediment age [3]. Analyzing clay minerals is complicated due to the mixture of numerous provenance and transport paths, and further geochemical analyses are necessary [6]. As smectite has a specific composition depending on the provenances, measuring the elemental composition of smectite is a potential way to solve this problem [7]. Analyses of the elemental composition of smectite at a nanoscale using transmission electron microscopy (TEM)
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