Your search keyword '"Moto Kawamata"' showing total 3 results

1. Regional sea-level highstand triggered Holocene ice sheet thinning across coastal Dronning Maud Land, East Antarctica

Author

Yusuke Suganuma, Heitaro Kaneda, Martim Mas e Braga, Takeshige Ishiwa, Takushi Koyama, Jennifer C. Newall, Jun’ichi Okuno, Takashi Obase, Fuyuki Saito, Irina Rogozhina, Jane Lund Andersen, Moto Kawamata, Motohiro Hirabayashi, Nathaniel A. Lifton, Ola Fredin, Jonathan M. Harbor, Arjen P. Stroeven, Ayako Abe-Ouchi, and University of St Andrews. School of Geography & Sustainable Development

Subjects

MCC, GC, QE Geology, General Earth and Planetary Sciences, QE, Geology, Geologi, GC Oceanography, DAS, SDG 14 - Life Below Water, General Environmental Science

Abstract

Funding: The field campaign was supported by the Japanese Antarctic Research program, the Norwegian Polar Institute/NARE, and SANAE IV Station. The permission for rock sampling in Antarctica has been approved by the ministry of the Environment, Japan. The study was supported by the JSPS Kakenhi (16H05739; 17H06321; 19H00728; 21H01173), the TOREY Science Foundation, NIPR through Advanced Project (KP-1), GRAntarctic, and MAGIC-DML (through grants from Stockholm University, the Norwegian Polar Institute – NARE, the US National Science Foundation (OPP-1542930), the Swedish Research Council, and the German Research Foundation). The high-resolution model experiments were enabled by resources provided by the Swedish National Infrastructure for Computing (SNIC) at the National Supercomputer Centre (NSC) partially funded by the Swedish Research Council through grant agreement no. 2018-05973. The East Antarctic Ice Sheet stores a vast amount of freshwater, which makes it the single largest potential contributor to future sea-level rise. However, the lack of well-constrained geological records of past ice sheet changes impedes model validation, hampers mass balance estimates, and inhibits examination of ice loss mechanisms. Here we identify rapid ice-sheet thinning in coastal Dronning Maud Land from Early to Middle Holocene (9000–5000 years ago) using a deglacial chronology based on in situ cosmogenic nuclide surface exposure dates from central Dronning Maud Land, in concert with numerical simulations of regional and continental ice-sheet evolution. Regional sea-level changes reproduced from our refined ice-load history show a highstand at 9000–8000 years ago. We propose that sea-level rise and a concomitant influx of warmer Circumpolar Deep Water triggered ice shelf breakup via the marine ice sheet instability mechanism, which led to rapid thinning of upstream coastal ice sheet sectors. Publisher PDF

Published

2022

2. Development of a portable percussion piston corer

Author

Kota Katsuki, Moto Kawamata, Yukiko Tanabe, Heitaro Kaneda, Daisuke Shibata, and Yusuke Suganuma

Subjects

Piston, law, General Engineering, General Earth and Planetary Sciences, Percussion, Mechanical engineering, Geology, General Environmental Science, law.invention

Published

2019

3. Multiproxy sedimentological and geochemical analyses across the Lower–Middle Pleistocene boundary: chemostratigraphy and paleoenvironment of the Chiba composite section, central Japan

Author

Kentaro Izumi, Takuya Matsuzaki, Makoto Okada, Yusuke Suganuma, Yuki Haneda, Yoshimi Kubota, Naohisa Nishida, and Moto Kawamata

Subjects

Marine isotope stage, 010504 meteorology & atmospheric sciences, δ18O, Geochemistry, 010502 geochemistry & geophysics, 01 natural sciences, Isotopes of oxygen, Chemostratigraphy, Organic matter, Chiba composite section, 0105 earth and related environmental sciences, chemistry.chemical_classification, Total organic carbon, GSSP, Terrigenous sediment, Kokumoto Formation, lcsh:QE1-996.5, lcsh:Geography. Anthropology. Recreation, Paleoenvironment, lcsh:Geology, lcsh:G, chemistry, Isotopes of carbon, General Earth and Planetary Sciences, Geology

Abstract

The Chiba composite section (CbCS) in the Kokumoto Formation, Kazusa Group, central Japan is a thick and continuous marine succession that straddles the Lower–Middle Pleistocene boundary and the well-recognized Matuyama–Brunhes paleomagnetic polarity boundary. Although recent studies extensively investigated the CbCS, its chemostratigraphy, particularly around the Lower–Middle Pleistocene boundary, is poorly understood. Therefore, in this study, we performed multiproxy sedimentological and geochemical analyses of the CbCS, including the Chiba section, which is the Global Boundary Stratotype Section and Point for defining the base of the Middle Pleistocene Subseries. The aim of these analyses is to establish the high-resolution chemostratigraphy and to reconstruct the paleoenvironments of its sedimentary basin in detail. We used the K/Ti ratio as a broad proxy for the clastic material grain size of the sediments. Although the K/Ti ratio generally varies throughout the studied interval, the K/Ti ratio especially during Marine Isotope Stage (MIS) 19a shows a variation pattern like those of the foraminiferal oxygen isotope (δ18O) records. The records of the C/N ratio of bulk samples and carbon isotope ratio of the organic carbon (δ13Corg) suggest that the organic matter in the CbCS sediments during MIS 19c mostly originated from marine plankton, whereas the organic matter during MIS 18 and 19a was characterized by a mixture of marine plankton and terrestrial plants. These records are clearly indicative of changes in mixing ratio of marine vs. terrestrial organic matter in association with glacial–interglacial cycles from the late MIS 20 to the early MIS 18. In addition, we calculated the mass accumulation rates (MARs) of organic carbon, biogenic carbonate, and terrigenous material for quantitative interpretations on the paleoenvironmental changes. MAR calculations revealed that the contribution of marine organic carbon relative to terrestrial organic carbon increased during MIS 19c, and that the contribution of the terrigenous material relative to biogenic carbonate decreased during MIS 19c. Furthermore, we observed relatively large variations in the total organic carbon and total nitrogen contents during MIS 19a. These variations were probably caused by the relative decrease in bottom-water oxygen level, which is also supported by our trace-fossil data, although it is not certain whether the increase in organic-carbon flux at ~ 760 ka was due to the synchronous increase in biogenic productivity in surface water. Such a relative decrease in bottom-water oxygen level was partly due to the increased ocean stratification because of the northward displacement of the Kuroshio Extension Front.

Published

2021