Browsing by Author "Nakamura, N"

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    Anisotropy of anhysteretic remanent magnetization (AARM) reveals cryptic flow fabric of tsunami
    (American Geophysical Union, 2013-12-09) Kon, S; Nakamura, N; Sugawara, D; Goto, K; Chagué-Goff, C; Goff, JR
    Sandy tsunami deposits may provide valuable information on tsunami inundation as well as hydrodynamics, such as flow speed. However, if the layer does not have sedimentary structures such as cross laminations, it is difficult to infer the flow direction, which is important to interpret the behavior of the tsunami, such as inflow and outflow as well as repetition of waves. Anisotropy of magnetic susceptibility (AMS), in combination with grain size data, can provide information about the hydrodynamic conditions prevailing during the emplacement of tsunami sequences. It might also allow the reconstruction of transport directions because it provides a cryptic alignment of ferromagnetic and paramagnetic minerals, such as coarse-grained magnetite or platy phyllosilicate minerals (e.g. biotite). These minerals behave differently in different hydrodynamic conditions: for example, platy biotite may deposit in a cryptic micro-ripple. This therefore suggests that the usefulness of bulk AMS together with optical observations is limited in the study of flow fabric in tsunami deposits. The anisotropy of anhysteretic remanent magnetization (AARM) on the other hand isolates the fine-grained magnetite subfabric of needle-shaped inclusions exsolved in silicate minerals. Samples (18) from tsunami deposits, believed to have been laid down by the Jogan event (869 AD), were collected from a section on the Sendai Plain, east Japan. The transport direction in these deposits could not be determined by AMS analysis due to large declination and inclination errors. The AARM technique was thus used to determine the cryptic subfabric of magnetite exsolutions along cleavages in biotite and amphibole. Our scanning electron microscopy (SEM) observations confirmed that the maximum AARM orientation is parallel to the needle-shaped magnetite microexsolutions in biotite and amphibole. We therefore infer that the large error of AMS is caused by the alteration of these paramagnetic minerals, and AARM provides a cryptic alignment of fine-grained magnetite microexsolutions. In order to apply this method to ancient historical Tsunami events, we also collected 40 samples from consecutive sand layers of possible tsunami deposits at 7 sites using 2 m long geoslicers in Rikuzen-Takata, northeast Japan. The AARM and SEM confirmed the tendency of same flow direction of sand layers at each site, suggesting a tsunami origin.
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    Geological evidence for the destruction of Shinmachi, Hawaii, by the 1946 Aleutian and 1960 Chile Tsunamis?
    (American Geophysical Union, 2016-12-12) Chagué-Goff, C; Goto, K; Goff, JR; Gadd, PS; Sugawara, D; Nakamura, N
    Around 1900, Japanese workers brought to Big Island, Hawaii, to work on the sugar plantations, established the Shinmachi (`New Town') community on low-lying land on Hilo's waterfront. Although Shinmachi was obliterated by the 1946 Aleutian tsunami, it was rebuilt, only to be totally destroyed again by the 1960 Chile tsunami. Shinmachi was never rebuilt and the site is now part of the Wailoa State Park. Short cores were collected throughout the park in an attempt to recover the geological evidence of these two tsunamis. Two anomalous layers, a lower sand (Unit 1) and an upper fining upward fine sand to silt (Unit 2) intercalated within soil and peat and exhibiting sharp lower and upper contacts, were recorded at only a few locations, probably reflecting, at least partly, the effect of anthropogenic disturbance and a limited amount of accommodation space on recent Holocene lava flows. One core was analysed by ITRAX core scanner equipped with a magnetic susceptibility (MS) meter. Unit 1 exhibits high MS associated with high Fe, Mn and Rb counts, but low Si and K counts, reflecting the volcanic composition of the material, and probably an older flooding event from the river. Unit 2 on the other hand is characterised by a different suite of elements, including Si, K, Ti, Mn, Fe, Ca, Sr, Zr and As. These most likely represent the mineralogical and chemical composition of shallow marine sediments from Hilo Bay and/or brackish sediments from Wailoa River estuary. High concentrations of As in particular have previously been reported in sediments from Hilo Bay and Wailoa River estuary and attributed to the release of arsenic trioxide by a canec manufacturing plant between 1932-1963. In this study, As was absent below Unit 2, and can thus be used as chronological control. Unit 2 therefore most likely represents the 1946 tsunami deposit. There was no clear evidence for the 1960 tsunami, probably reflecting the limited amount of accommodation space in the area.
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    Magnetic anisotropies for tsunami deposits: application to the 3.11
    (Japan Geoscience Union, 2013-05-24) Kon, S; Nakamura, N; Goto, K; Sugawara, D; Iijima, Y; Chagué-Goff, C; Goff, JR
    Tsunami deposits consist of well-sorted fine sand intercalating with non-marine black organic mud. It is difficult to reveal a transport direction of the deposit if the deposit showed no sedimentary fabrics,such as ripples. The proxy of anisotropy of magnetic susceptibility (AMS) appears to be a promising tool for the study of flow fabrics in recent-tsunami deposits such as Sumatra tsunami (Wassmer et al. 2010). The AMS fabric might allow us to reconstruct transport directions of unconsolidated tsunami sediments during emplacement because AMS provides a cryptic alignment of ferromagnetic and paramagnetic minerals. Such cryptic minerals, such as magnetite or phyllosilicate minerals, would behave as a different emplacement mode in a different hydrodynamic condition. In the AMS fabrics of volcanic rocks, there are large discrepancies between the magnetic lineation and the framework-forming silicate linear fabric. This suggests that the uncorroborated use of bulk AMS to detect flow fabric in tsunami deposits has risks. In this article, we show that the anisotropy of anhysteretic remanent magnetization (AARM) may resolve the difficulties. The combination of inundation eye-witness, SEM, AMS, and AARM confirms the flow pattern of recentand paleo-tsunami deposits from the geoslicer sampleing at Rikuzen-Takata city, Japan during 2011, 11th March Tohoku tsunami. We determined if the sandy deposits are of tsunami from these magnetic anisotropies. © 2013, Japan Geoscience Union.
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    Possible paleo-tsunami deposits at Rikuzentakata City, Japan
    (National Committee of Japan for IGU, 2013-08-05) Iijima, Y; Sugawara, D; Goto, K; Chagué-Goff, C; Hayase, R; Hashimoto, K; Kon, S; Nakamura, N; Goff, JR
    Rikuzentakata City, NE Japan, has been repeatedly suffered by tsunami inundations including 1896 Meiji-Sanriku, 1933 Showa-Sanriku, 1960 Chilean Tsunami, and 2011 Tohoku-Oki Tsunami. Up to 30 cm thick sand layer was deposited by the 2011 tsunami in this city (Naruse et al., 2012). Our study indicates that historical and prehistoric tsunamis also left deposits in this area. Nevertheless, previous studies of paleo-tsunami deposits in this area are limited (Haraguchi et al., 2006, Imaizumi et al., 2007), because of the difficulty of finding paleo-tsunami deposits along this ""ria"" coast. We conducted a field survey using a geoslicer to acquire sediment cores in order to explore the magnitude and history of tsunamis in this area. Overall 10 cores, each 2 m long and 12 cm wide were acquired during the survey. The sedimentary sequences were mostly composed of peaty soil, which was thought to have been deposited in a marsh environment, however these soils units were inter-fingered by numerous 1-15 cm thick sand layers. According to initial work including grain size analysis, some of the sand layers deposited 1.4 km from the present shoreline are identified as having a possible tsunami origin because they tend to show upward fining characteristics, indicating rapid sedimentation from suspended load. We will also present the preliminary results of tephra chronology, radiocarbon and 210Pb dating, and diatom analysis.