Oceanography in Japan
Online ISSN : 2186-3105
Print ISSN : 0916-8362
ISSN-L : 0916-8362
Volume 5, Issue 2
Displaying 1-2 of 2 articles from this issue
  • Masato Kamizono, Takuya Etoh, Hiroyuki Satoh
    1996 Volume 5 Issue 2 Pages 87-95
    Published: April 30, 1996
    Released on J-STAGE: April 14, 2008
    JOURNAL FREE ACCESS
    To clarify the oxygen budget in the bottom layer of the southwestern part of Suo-Nada, we measured the oxygen consumption and production rates of the bottom sea water, sinking particles and bottom sediment in laboratory conditions from July to August, 1995. Then we also measured the contents of organic carbon, chlorophyll a and pheo-pigments in these substances. The mean total oxygen consumption rate in the bottom layer was 2.85g O2/m2/day; ca. 72% was caused by the bottom sea water, ca. 26% by the bottom sediment and ca. 2% by the sinking particles. On the other hand, the mean total oxygen production rate was 1.40g O2/m2/day; ca. 98% was caused by the bottom sea water and ca. 2% by the sinking particles. These results suggest that the oxygen consumption rates and the oxygen production rates by the bottom sea water play important roles in the formation of the oxygen deficient water mass in this water.
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  • Yoshihisa Kato, Tatsuo Miyata, Hideki Wada, Hideki Minami
    1996 Volume 5 Issue 2 Pages 97-106
    Published: April 30, 1996
    Released on J-STAGE: April 14, 2008
    JOURNAL FREE ACCESS
    Three drill sediment cores, which penetrated throughout the Holocene, were collected in 1985 from the bottom of a coastal brackish lake, Lake Hamana, Japan. Chlorinity in pore waters extracted form the sediment samples was determined. In 2 cores by the ocean side, chlorinity is low in the upper and lower silt layers and high in the middle fine sand layers. However, the core in the most-inland site is composed of silty clay at the whole depth, and chlorinity gradually decreases from 16.67 g kg&lt-1&gt in the surface layer, closely to that in the lake bottom water, to 1.35 g kg&lt-1&gt at the bottom depth of 5.32 m. Using non-steady state diffusion-advection models, the distributions of chlorinity in cores from the ocean and most-inland sides were analyzed. The comparisons between measured and predicted distributions suggest as follows; (1) from the ocean side core the salt water is laterally transported from the sea to the lake through the sandy sediment layer, and (2) from the inland side core the elapsed time while chloride in the lake water diffuses into the sediment is estimated to be 200-300 years at least, and therefore the recent increase in salt concentration of the lake water can be attributed to the change of the mixing rate of oceanic water and fresh lake water by mainly giant tsunami disasters since the early 18th century.
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