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Spatial Distribution of Δ14C Values of Organic Matter in Surface Sediments Off Saru River in Northern Japan, One Year After a Flood Event in 2006

Published online by Cambridge University Press:  18 July 2016

Seiya Nagao ,
Tomohisa Irino ,
Takafumi Aramaki ,
Ken Ikehara ,
Hajime Katayama ,
Shigeyoshi Otosaka ,
Masao Uchida  and
Yasuyuki Shibata
Seiya Nagao*
Affiliation:
Low Level Radioactivity Laboratory, Institute of Nature and Environmental Technology, Kanazawa University, Wake, Nomi, Ishikawa 923-1224, Japan
Tomohisa Irino
Affiliation:
Faculty of Environmental Earth Science, Hokkaido University, N10W5, Kita-ku, Sapporo, Hokkaido 060-0810, Japan
Takafumi Aramaki
Affiliation:
Environmental Chemistry Division, National Institute for Environmental Studies, 16-2 Onogawa, Tsukuba, Ibaraki 305-8506, Japan
Ken Ikehara
Affiliation:
Marine Geological Research Group, Geological Survey of Japan, National Institute of Advanced Industrial Science and Technology, 1-1-1 Higashi, Tsukuba, Ibaraki 305-8567, Japan
Hajime Katayama
Affiliation:
Marine Geological Research Group, Geological Survey of Japan, National Institute of Advanced Industrial Science and Technology, 1-1-1 Higashi, Tsukuba, Ibaraki 305-8567, Japan
Shigeyoshi Otosaka
Affiliation:
Nuclear Science and Engineering Directorate, Japan Atomic Energy Agency, 2-4 Shirakata Shirane, Tokai, Ibaraki 319-1195, Japan
Masao Uchida
Affiliation:
Environmental Chemistry Division, National Institute for Environmental Studies, 16-2 Onogawa, Tsukuba, Ibaraki 305-8506, Japan
Yasuyuki Shibata
Affiliation:
Environmental Chemistry Division, National Institute for Environmental Studies, 16-2 Onogawa, Tsukuba, Ibaraki 305-8506, Japan
*
Corresponding author. Email: s_nagao@llrl.ku-unet.ocn.ne.jp
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Abstract

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Dispersion and deposition of terrestrial organic matter by flooding on the inner shelf were studied using C/N ratios, δ13C, and Δ14C values of sedimentary organic matter. Surface sediment samples (top 2 cm) were collected from coastal areas near the Saru River in southwestern Hokkaido, northern Japan, 1 yr after a flood event in 2006. Riverine suspended solids were also collected at a fixed station downstream during 2006–2008. Sandy sediments were located at the front of the river mouth and the western part of the sampling area, with the δ13C of organic matter ranging from −23.8‰ to −22.0‰, Δ14C of –655‰ to –388‰, and an organic carbon/total nitrogen (C/N) ratio of 5.9–7.7. On the other hand, silt and clay sediments were distributed in a restricted area 11–16 km from the river mouth, with lighter δ13C (–26.7‰ to −24.1‰) and higher Δ14C (–240‰ to –77‰) of organic matter and C/N ratio (7.8–13.3). From end-member analysis, the apparently younger and less degraded organic matter in the silt and clay sediments consists mainly of terrestrial organic matter released by flood events. They remain in the depression, although most flood deposits were moved to deep-sea environments.

Type
Freshwater and Groundwater
Information
Radiocarbon , Volume 52 , Issue 3: 20th Int. Radiocarbon Conference Proceedings , 2010 , pp. 1068 - 1077
Copyright
Copyright © 2010 by the Arizona Board of Regents on behalf of the University of Arizona 

References

Aramaki, T, Mizushima, T, Mizutani, Y, Yamamoto, T, Togawa, O, Kabuto, S, Kuji, T, Gottdang, A, Klein, M, Mous, DJW. 2000. The AMS facility at the Japan Atomic Energy Research Institute (JAERI). Nuclear Instruments and Methods in Physics Research B 172(1–4):107–11.Google Scholar
Balesdent, J, Girardin, C, Mariotti, A. 1993. Site-related δ13C of tree leaves and soil organic matter in a temperate forest. Ecology 74(6):1713–21.Google Scholar
Berner, RA. 1982. Burial of organic carbon and pyrite sulfur in the modern ocean: its geochemical and environmental signature. American Journal of Science 282:451–73.Google Scholar
Blair, NE, Leithold, EL, Ford, ST, Peeler, KA, Holmes, JC, Perkey, DW. 2003. The persistence of memory: the fate of ancient sedimentary organic carbon in a modern sedimentary system. Geochimica et Cosmochimica Acta 67(1):6373.Google Scholar
Goñi, MA, Ruttenberg, KC, Eglinton, TI. 1997. Sources and contribution of terrigenous organic carbon to surface sediments in the Gulf of Mexico. Nature 389(6648):275–8.Google Scholar
Goñi, MA, Yunker, MB, Macdonald, RW, Eglinton, TI. 2005. The supply and preservation of ancient and modern components of organic carbon in the Canadian Beaufort Shelf of the Arctic Ocean. Marine Chemistry 93(1):5373.Google Scholar
Guo, L, Semiletov, I, Gustafsson, Ö, Ingri, J, Andersson, P, Dudarev, O, White, D. 2004. Characterization of Siberian Arctic coastal sediments: implications for terrestrial organic export. Global Biogeochemical Cycles 18: GB1036, doi:10.1029/2003GB002087.Google Scholar
Hedges, J, Keil, RG. 1995. Sedimentary organic matter preservation: an assessment and speculative synthesis. Marine Chemistry 49(2–3):81115.Google Scholar
Hellings, L, Dehairs, F, Tackx, M, Keppens, E, Baeyens, W. 1999. Origin and fate of organic carbon in the freshwater part of the Scheldt Estuary as traced by stable carbon isotope composition. Biogeochemistry 47(2):167–86.Google Scholar
Hokkaido Regional Development Bureau. 2006. The bulletin board on heavy rain disaster and its corresponding state by the stationary front on August 17–19 in 2006. Hokkaido. p 27. In Japanese.Google Scholar
Hokkaido Regional Development Bureau. 2007. Reports of Development Plan for the Saru River System. Revised version. Hokkaido. In Japanese.Google Scholar
Ikehara, K, Katayama, H, Tsujino, T, Inoue, T, Suga, K, Sagayama, T, Irino, T, Omura, A. 2006. Inner shelf topographical control on flood sediment transport: example from Hidaka shelf, northern Japan. AGU Fall Meeting 2006, Abstract OS23A–1627.Google Scholar
Japan Meteorological Agency. 2009. Climate statistics. URL: http://www.jma.go.jp/jma/menu/report.html. Accessed 1 July 2009. In Japanese.Google Scholar
Kamei, K. 2006. Outline of flood disaster in the Districts of Hidaka and Tokachi, Hokkaido. In: Natural Disaster Research Report of the National Research Institute for Earth Science and Disaster Prevention 39. p 16. In Japanese Google Scholar
Kao, S-J, Liu, K-K. 1996. Particulate organic carbon export from a subtropical mountainous river (Lanyang His) in Taiwan. Limnology and Oceanography 41(8):1749–57.Google Scholar
Katayama, H. 2007. Marine geological and geophysical studies of the collision zone of Kurile and northeast Japan Arcs, off Hidaka Area. GSJ Interim Report 39, AIST, Tsukuba. 171 p. In Japanese.Google Scholar
Katayama, H, Ikehara, K, Suga, K, Sagayama, T, Irino, T, Tujino, T, Inoue, T. 2007. Distribution of surface sediments after the 2003 flood on the shelf off Hidaka, southern Hokkaido. Bulletin of the Geological Survey of Japan 58(5–6):189–99. In Japanese with English abstract.Google Scholar
Kendall, C, Silva, SR, Kelly, VJ. 2001. Carbon and nitrogen isotopic compositions of particulate organic matter in four large river systems across the United States. Hydrological Processes 15(7):1301–46.Google Scholar
Koarashi, J, Iida, T, Asano, T. 2005. Radiocarbon and stable carbon isotope compositions of chemically fractionated soil organic matter in a temperate-zone forest. Journal of Environmental Radioactivity 79(2):137–56.Google Scholar
Liu, W, Moriizumi, J, Yamazawa, H, Iida, T. 2006. Depth profiles of radiocarbon and carbon isotopic compositions of organic matter and CO2 in a forest soil. Journal of Environmental Radioactivity 90(3):210–23.Google Scholar
Melillo, JM, Aber, JD, Linkins, AE, Ricca, A, Fry, B, Nadelhoffer, KJ. 1989. Carbon and nitrogen dynamics along the decay continuum: plant litter to soil organic matter. Plant and Soil 115(2):189–98.Google Scholar
Ministry of Land, Infrastructure, Transport and Tourism, Japan. 2009. Water information system. URL: http://www1.rivers.go.jp/. Accessed 1 July 2009. In Japanese.Google Scholar
Miserocchi, S, Faganeli, J, Balboni, V, Heussner, S, Monaco, A, Kerherve, P. 1999. Characteristics and sources of the settling particulate organic matter in the South Adriatic Basin. Organic Geochemistry 30(6):411–21.Google Scholar
Miserocchi, S, Langone, L, Tommaso, T. 2007. Content and isotopic composition of organic carbon within a flood layer in the Po River prodelta (Adriatic Sea). Continental Shelf Research 27(3–4):338–58.Google Scholar
Mongin, M, Nelson, DM, Pondaven, PP, Brzezinski, MA, Tréguer, P. 2003. Simulation of upper-ocean biogeochemistry with a flexible-composition phytoplankton model: C, N and Si cycling in the western Sargasso Sea. Deep-Sea Research I 50(12):1445–80.Google Scholar
Nagano, T, Yanase, N, Tsuduki, T, Nagao, S. 2003. Particulate and dissolved elemental loads in the Kuji River related to discharge rate. Environmental International 28(7):649–58.Google Scholar
Nagao, S, Usui, T, Yamamoto, M, Minagawa, M, Iwatsuki, T, Noda, A. 2005. Combined use of Δ14C and δ13C values to trace terrestrial particulate organic matter in coastal marine environments. Chemical Geology 218(1–2):6372.Google Scholar
Nieuwerburgh, LV, Wanstrand, I, Snoeijs, P. 2004. Growth and C: N: P ratios in copepods grazing on N- or Si-limited phytoplankton blooms. Hydrobiologia 514(1–3):5772.Google Scholar
Onstad, GD, Canfield, DE, Quay, PD, Hedges, JI. 2000. Sources of particulate organic matter in rivers from the continental USA: lignin phenol and stable carbon isotope compositions. Geochimica et Cosmochimica Acta 64(20):3539–46.Google Scholar
Rau, GH, Sweeney, RE, Kaplan, IR. 1982. Plankton 13C: 12C ratio changes with latitude: differences between northern and southern oceans. Deep-Sea Research A 29(8):1035–9.Google Scholar
Raymond, PA, Bauer, JE. 2001. Use of 14C and 13C natural abundances for evaluating riverine, estuarine, and coastal DOC and POC sources and cycling: a review and synthesis. Organic Geochemistry 32(4):469–85.Google Scholar
Stuiver, M, Polach, HA. 1977. Discussion: reporting of 14C data. Radiocarbon 19(3):355–63.Google Scholar
Tanaka, A, Yoneda, M, Uchida, M, Uehiro, T, Shibata, Y, Morita, M 2000. Recent advances in 14C measurements at NIES-TERRA. Nuclear Instruments and Methods in Physics Research B 172(1–4):107–11.Google Scholar
Tesi, T, Langone, L, Goñi, MA, Miserocchi, S, Bertasi, F. 2008. Changes in the composition of organic matter from prodeltaic sediments after a large flood event (Po River, Italy). Geochimica et Cosmochimica Acta 72(8):2100–14.Google Scholar
Trumbore, S. 2000. Age of soil organic matter and soil respiration: radiocarbon constrains on belowground C dynamics. Ecological Applications 10(2):399411.Google Scholar
Trumbore, SE, Davidson, EA, De Camargo, PB, Nepstad, DC, Martinelli, LA. 1995. Belowground cycling of carbon in forest and pastures of eastern Amazonia. Global Biogeochemical Cycles 9(4):515–28.Google Scholar
Usui, T, Nagao, S, Yamamoto, M, Suzuki, K, Kudo, I, Montani, S, Noda, A, Minagawa, M. 2006. Distribution and sources of organic matter in surfacial sediments on the shelf and slope off Tokachi, western North Pacific, inferred from C and N stable isotopes and C/N ratios. Marine Chemistry 98(2–4):241–59.Google Scholar
Wang, X-C, Druffel, ERN, Griffin, S, Lee, C, Kashgarian, M. 1998. Radiocarbon studies of organic compound classes in plankton and sediment of the northeastern Pacific Ocean. Geochimica et Cosmochimica Acta 62(8):1365–78.Google Scholar
Yamashita, T. 2004. Behavior of fine particles in coastal environments. Disaster Research Report of Heavy Rain in Hokkaido by Typhoon No. 10 in 2003. Committee on Hydroscience and Hydraulic Engineering, Japan Society of Civil Engineers. In Japanese.Google Scholar
Yamashita, T, Kasuya, N, Nishimura, S, Takeda, H. 2004. Comparison of two coniferous plantations in central Japan with respect to forest productivity, growth phenology and soil nitrogen dynamics. Forest Ecology and Management 200(1–3):215–26.Google Scholar