南海深層短半衰期釷放射核種的沉降通量時序變化

Ying-Ying Chen; 陳映穎

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/50322

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	魏慶琳(Ching-Ling Wei)
dc.contributor.author	Ying-Ying Chen	en
dc.contributor.author	陳映穎	zh_TW
dc.date.accessioned	2021-06-15T12:36:18Z	-
dc.date.available	2019-08-24
dc.date.copyright	2016-08-24
dc.date.issued	2016
dc.date.submitted	2016-07-29
dc.identifier.citation	Armstrong, R.A., Peterson, M.L., Lee, C., Wakeham, S.G., 2009. Settling velocity spectra and the ballast ratio hypothesis. Deep Sea Research II 56: 1470–1478. Bacon, M.P., Anderson, R.F., 1982. Distribution of thorium isotopes between dissolved and particulate forms in the deep sea. Journal of Geophysical Research 87: 2045–2056. Bacon, M.P., Huh, C.-A., Fleer, A.P., Deuser, W.G., 1985. Seasonality in the flux of natural radionuclides and plutonium in the deep Sargasso Sea. Deep Sea Research I 32: 273–286. Bhat, S.G., Krishnaswamy, S., Lal, D., Rama, Moore, W.S., 1968. 234Th/238U ratios in the ocean. Earth and Planetary Science Letters 5: 483–491. Brewer, P.G., Nozaki, Y., Spencer, D.W., Fleer, A.P., 1980. Sediment trap experiments in the deep North Atlantic: isotopic and elemental fluxes. ResearchGate 38:4. Broecker, W.S., Kaufman, A., Trier, R.M., 1973. The residence time of thorium in surface sea water and its implications regarding the rate of reactive pollutants. Earth and Planetary Science Letters 20: 35–44. Bruland, K.W., Franks, R.P., Landing, W.M., Soutar, A., 1981. Southern California inner basin sediment trap calibration. Earth and Planetary Science Letters 53: 400–408. Buesseler, K., Ball, L., Andrews, J., Benitez-Nelson, C., Belastock, R., Chai, F., Chao, Y., 1998. Upper ocean export of particulate organic carbon in the Arabian Sea derived from thorium-234. Deep Sea Research II 45: 2461–2487. Buesseler, K.O., Antia, A.N., Chen, M., Fowler, S.W., Gardner, W.D., Gustafsson, Ö., Harada, K., Michaels, A.F., Rutgers v. d. Loeff, M., Sarin, M., Steinberg, D.K., Trull, T., 2007. An assessment of the use of sediment traps for estimating upper ocean particle fluxes. Journal of Marine Research 65: 345–416. Buesseler, K.O., Bacon, M.P., Kirk Cochran, J., Livingston, H.D., 1992. Carbon and nitrogen export during the JGOFS North Atlantic Bloom experiment estimated from 234Th: 238U disequilibria. Deep Sea Research I 39: 1115–1137. Buesseler, K.O., Benitez-Nelson, C.R., Moran, S.B., Burd, A., Charette, M., Cochran, J.K., Coppola, L., Fisher, N.S., Fowler, S.W., Gardner, W.D., Guo, L.D., Gustafsson, Ö., Lamborg, C., Masque, P., Miquel, J.C., Passow, U., Santschi, P.H., Savoye, N., Stewart, G., Trull, T., 2006. An assessment of particulate organic carbon to thorium-234 ratios in the ocean and their impact on the application of 234Th as a POC flux proxy. Marine Chemistry 100: 213–233. Buesseler, K.O., Lamborg, C., Cai, P., Escoube, R., Johnson, R., Pike, S., Masque, P., McGillicuddy, D., Verdeny, E., 2008. Particle fluxes associated with mesoscale eddies in the Sargasso Sea. Deep Sea Research II 55: 1426–1444. Buesseler, K.O., Pike, S., Maiti, K., Lamborg, C.H., Siegel, D.A., Trull, T.W., 2009. Thorium-234 as a tracer of spatial, temporal and vertical variability in particle flux in the North Pacific. Deep Sea Research I 56: 1143–1167. Cai, P., Chen, W., Dai, M., Wan, Z., Wang, D., Li, Q., Tang, T., Lv, D., 2008. A high-resolution study of particle export in the southern South China Sea based on 234Th: 238U disequilibrium. Journal of Geophysical Research 113: C04019. Cai, P., Dai, M., Chen, W., Tang, T., Zhou, K., 2006. On the importance of the decay of 234Th in determining size-fractionated C/234Th ratio on marine particles. Geophysical Research Letters 33: L23602. Cai, P., Huang, Y., Chen, M., Guo, L., Liu, G., Qiu, Y., 2002a. New production based on 228Ra-derived nutrient budgets and thorium-estimated POC export at the intercalibration station in the South China Sea. Deep Sea Research I 49: 53–66. Cai, P., Huang, Y., Chen, M., Liu, G., Qiu, Y., 2002b. New production in the South China Sea - A coupled 228Ra-nitrate approach. Science in China Series D 45: 103. Cai, P., Zhao, D., Wang, L., Huang, B., Dai, M., 2015. Role of particle stock and phytoplankton community structure in regulating particulate organic carbon export in a large marginal sea. Journal of Geophysical Research 120: 2063–2095. Chen, W., Cai, P., Dai, M., Wei, J., 2008. 234Th/238U disequilibrium and particulate organic carbon export in the northern South China Sea. Journal of Oceanography 64: 417–428. Chen, W., Liu, Q., Huh, C.-A., Dai, M., Miao, Y.-C., 2010. Signature of the Mekong River plume in the western South China Sea revealed by radium isotopes. Journal of Geophysical Research 115: C12002. Chen, Y.L., 2005. Spatial and seasonal variations of nitrate-based new production and primary production in the South China Sea. Deep Sea Research I 52: 319–340. Chen, Y.L., Chen, H.-Y., Chung, C.-W., 2007. Seasonal variability of coccolithophore abundance and assemblage in the northern South China Sea. Deep Sea Research II 54: 1617–1633. Chuang, C.-Y., Santschi, P.H., Ho, Y.-F., Conte, M.H., Guo, L., Schumann, D., Ayranov, M., Li, Y.-H., 2013. Role of biopolymers as major carrier phases of Th, Pa, Pb, Po, and Be radionuclides in settling particles from the Atlantic Ocean. Marine Chemistry 157: 131–143. Chung, Y., Chang, H.C., Hung, G.W., 2004. Particulate flux and 210Pb determined on the sediment trap and core samples from the northern South China Sea. Continental Shelf Research 24: 673–691. Clegg, S.L., Whitfield, M., 1991. A generalized model for the scavenging of trace metals in the open ocean—II. Thorium scavenging. Deep Sea Research I 38: 91–120. Coale, K.H., Bruland, K.W., 1987. Oceanic stratified euphotic zone as elucidated by 234Th: 238U disequilibria. Limnology and Oceanography 32: 189–200. Coale, K.H., Bruland, K.W., 1985. 234Th: 238U disequilibria within the California Current. Limnology and Oceanography 30: 22–33. Cochran, J.K., Buesseler, K.O., Bacon, M.P., Livingston, H.D., 1993. Thorium isotopes as indicators of particle dynamics in the upper ocean: results from the JGOFS North Atlantic Bloom experiment. Deep Sea Research I 40: 1569–1595. Cochran, J.K., Buesseler, K.O., Bacon, M.P., Wang, H.W., Hirschberg, D.J., Ball, L., Andrews, J., Crossin, G., Fleer, A., 2000. Short-lived thorium isotopes (234Th, 228Th) as indicators of POC export and particle cycling in the Ross Sea, Southern Ocean. Deep Sea Research II 47: 3451–3490. Cochran, J.K., Miquel, J.C., Armstrong, R., Fowler, S.W., Masqué, P., Gasser, B., Hirschberg, D., Szlosek, J., Rodriguez y Baena, A.M., Verdeny, E., Stewart, G.M., 2009. Time-series measurements of 234Th in water column and sediment trap samples from the northwestern Mediterranean Sea. Deep Sea Research II 56: 1487–1501. Conte, M.H., Ralph, N., Ross, E.H., 2001. Seasonal and interannual variability in deep ocean particle fluxes at the Oceanic Flux Program (OFP)/Bermuda Atlantic Time Series (BATS) site in the western Sargasso Sea near Bermuda. Deep Sea Research II 48: 1471–1505. Conte, M.H., Weber, J.C., Ralph, N., 1998. Episodic particle flux in the deep Sargasso Sea. Deep Sea Research I 45: 1819–1841. Deuser, W.G., Ross, E.H., Anderson, R.F., 1981. Seasonality in the supply of sediment to the deep Sargasso Sea and implications for the rapid transfer of matter to the deep ocean. Deep Sea Research I 28: 495–505. Fasham, M.J.R., Balino, B.M., Bowles, M.C., Anderson, R., Archer, D., Bathmann, U., Boyd, P., Buesseler, K., Burkill, P., Bychkov, A., Carlson, C., Chen, C.T.A., Doney, S., Ducklow, H., Emerson, S., Feely, R., Feldman, G., Garcon, V., Hansell, D., Hanson, R., Harrison, P., Honjo, S., Jeandel, C., Karl, D., Le Borgne, R., Liu, K.K., Lochte, K., Louanchi, F., Lowry, R., Michaels, A., Monfray, P., Murray, J., Oschlies, A., Platt, T., Priddle, J., Quinones, R., Ruiz-Pino, D., Saino, T., Sakshaug, E., Shimmield, G., Smith, S., Smith, W., Takahashi, T., Treguer, P., Wallace, D., Wanninkhof, R., Watson, A., Willebrand, J., Wong, C.S., 2001. A new vision of ocean biogeochemistry after a decade of the Joint Global Ocean Flux Study (JGOFS). Ambio: 4-31. Fisher, N.S., Cochran, J.K., Krishnaswami, S., Livingston, H.D., 1988. Predicting the oceanic flux of radionuclides on sinking biogenic debris. Nature 335: 622–625. Gaye, B., Wiesner, M.G., Lahajnar, N., 2009. Nitrogen sources in the South China Sea, as discerned from stable nitrogen isotopic ratios in rivers, sinking particles, and sediments. Marine Chemistry 114: 72–85. Guo, L., Santschi, P.H., Baskaran, M., 1997. Aquatic Colloid and Surface ChemistryInteractions of thorium isotopes with colloidal organic matter in oceanic environments. Colloids and Surfaces 120: 255–271. Harada, K., Tsunogai, S., 1986. Fluxes of 234Th, 210Po and 210Pb determined by sediment trap experiments in pelagic Oceans. Journal of the Oceanographical Society of Japan 42: 192–200. Hiwatari, T., Shirasawa, K., Fukamachi, Y., Nagata, R., Koizumi, T., Koshikawa, H., Kohata, K., 2008. Vertical material flux under seasonal sea ice in the Okhotsk Sea north of Hokkaido, Japan. Polar Science 2: 41–54. Hodge, V.F., Koide, M., Goldberg, E.D., 1979. Particulate uranium, plutonium and polonium in the biogeochemistries of the coastal zone. Nature 277: 206–209. Honda, M.C., Imai, K., Nojiri, Y., Hoshi, F., Sugawara, T., Kusakabe, M., 2002. The biological pump in the northwestern North Pacific based on fluxes and major components of particulate matter obtained by sediment-trap experiments (1997–2000). Deep Sea Research II 49: 5595–5625. Honeyman, B.D., Balistrieri, L.S., Murray, J.W., 1988. Oceanic trace metal scavenging: the importance of particle concentration. Deep Sea Research I 35: 227–246. Honeyman, B.D., Santschi, P.H., 1989. A Brownian-pumping model for oceanic trace metal scavenging: Evidence from Th isotopes. Journal of Marine Research 47: 951–992. Hong, G.-H., Baskaran, M., Lee, H.-K., Kim, S.-H., 2008. Sinking fluxes of particulate U-Th radionuclides in the East Sea (Sea of Japan). Journal of Oceanography 64: 267–276. Honjo, S., Doherty, K.W., Agrawal, Y.C., Asper, V.L., 1984. Direct optical assessment of large amorphous aggregates (marine snow) in the deep ocean. Deep Sea Research I 31: 67–76. Honjo, S., Dymond, J., Collier, R., Manganini, S.J., 1995. Export production of particles to the interior of the equatorial Pacific Ocean during the 1992 EqPac experiment. Deep Sea Research II 42: 831–870. Honjo, S., Dymond, J., Prell, W., Ittekkot, V., 1999. Monsoon-controlled export fluxes to the interior of the Arabian Sea. Deep Sea Research II 46: 1859–1902. Honjo, S., Manganini, S.J., 1993. Annual biogenic particle fluxes to the interior of the North Atlantic Ocean; studied at 34°N 21°W and 48°N 21°W. Deep Sea Research II 40: 587–607. Honjo, S., Manganini, S.J., Cole, J.J., 1982. Sedimentation of biogenic matter in the deep ocean. Deep Sea Research I 29: 609–625. Huh, C.-A., Ku, T.-L., Luo, S., Landry, M.R., Williams, P.M., 1993. Fluxes of Th isotopes in the Santa Monica Basin, offshore California. Earth and Planetary Science Letters 116: 155–164. Huh, C.-A., Small, L.F., Niemnil, S., Finney, B.P., Hickey, B.M., Kachel, N.B., Gorsline, D.S., Williams, P.M., 1990. Sedimentation dynamics in the Santa Monica-San Pedro Basin off Los Angeles: radiochemical, sediment trap and transmissometer studies. Continental Shelf Research 10: 137–164. Huh, C.-A., Wei, C.-L., 1995. Thorium Isotopes as Tracers of Chemical Scavenging and Particle Dynamics in the Ocean: Review and Perspective. Acta Oceanographica Taiwanica 34: 17–30. Hung, C.-C., Gong, G.-C., 2010. POC/234Th ratios in particles collected in sediment traps in the northern South China Sea. Estuarine, Coastal and Shelf Science 88: 303–310. Ittekkot, V., 1991. Particle flux studies in the Indian Ocean. Eos Trans. AGU 72: 527–530. Jeandel, C., Rutgers van der Loeff, M., Lam, P.J., Roy-Barman, M., Sherrell, R.M., Kretschmer, S., German, C., Dehairs, F., 2015. What did we learn about ocean particle dynamics in the GEOSECS–JGOFS era? Progress in Oceanography 133: 6–16. Karl, D.M., Christian, J.R., Dore, J.E., Hebel, D.V., Letelier, R.M., Tupas, L.M., Winn, C.D., 1996. Seasonal and interannual variability in primary production and particle flux at Station ALOHA. Deep Sea Research II 43: 539–568. Kaufman, A., Li, Y.-H., Turekian, K.K., 1981. The removal rates of 234Th and 228Th from waters of the New York Bight. Earth and Planetary Science Letters 54: 385–392. Kim, G., Church, T.M., 2001. Seasonal biogeochemical fluxes of 234Th and 210Po in the Upper Sargasso Sea: Influence from atmospheric iron deposition. Global Biogeochemical Cycles 15: 651–661. Knauss, K.G., Ku, T.-L., Moore, W.S., 1978. Radium and thorium isotopes in the surface waters of the East Pacific and coastal Southern California. Earth and Planetary Science Letters 39: 235–249. Ku, T.-L., Knauss, K.G., Mathieu, G.G., 1977. Uranium in open ocean: concentration and isotopic composition. Deep Sea Research 24: 1005–1017. Lahajnar, N., Wiesner, M.G., Gaye, B., 2007. Fluxes of amino acids and hexosamines to the deep South China Sea. Deep Sea Research I 54: 2120–2144. Lam, P.J., Marchal, O., 2015. Insights into Particle Cycling from Thorium and Particle Data. Annual Review of Marine Science 7: 159–184. Lee, C., Peterson, M.L., Wakeham, S.G., Armstrong, R.A., Cochran, J.K., Miquel, J.C., Fowler, S.W., Hirschberg, D., Beck, A., Xue, J., 2009. Particulate organic matter and ballast fluxes measured using time-series and settling velocity sediment traps in the northwestern Mediterranean Sea. Deep Sea Research II 56: 1420–1436. Lin, P., Chen, M., Guo, L., 2015. Effect of natural organic matter on the adsorption and fractionation of thorium and protactinium on nanoparticles in seawater. Marine Chemistry 173: 291–301. Liu, K.-K., Atkinson, L., Quinones, R., Talaue-McManus, L., 2010. Carbon and Nutrient Fluxes in Continental Margins: A Global Synthesis. Springer Science & Business Media. Li, Y.-H., Santschi, P.H., Kaufman, A., Benninger, L.K., Feely, H.W., 1981. Natural radionuclides in waters of the New York Bight. Earth and Planetary Science Letters 55: 217–228. Luo, S., Ku, T.-L., Kusakabe, M., Bishop, J.K.B., Yang, Y.-L., 1995. Tracing particle cycling in the upper ocean with 230Th and 228Th: An investigation in the equatorial Pacific along 140°W. Deep Sea Research II 42: 805–829. Ma, H., Zeng, Z., He, J., Chen, L., Yin, M., Zeng, S., Zeng, W., 2008. Vertical flux of particulate organic carbon in the central South China Sea estimated from 234Th-238U disequilibria. Chinese Journal of Oceanology and Limnology 26: 480–485. Marchal, O., Lam, P.J., 2012. What can paired measurements of Th isotope activity and particle concentration tell us about particle cycling in the ocean? Geochimica et Cosmochimica Acta 90: 126–148. Matsumoto, E., 1975. 234Th-238U radioactive disequilibrium in the surface layer of the ocean. Geochimica et Cosmochimica Acta 39: 205–212. Moore, W.S., 2000. Determining coastal mixing rates using radium isotopes. Continental Shelf Research 20: 1993–2007. Moore, W.S., 1981. The thorium isotope content of ocean water. Earth and Planetary Science Letters 53: 419–426. Moore, W.S., 1969. Measurement of Ra228 and Th228 in sea water. Journal of Geophysical Research 74: 694–704. Müller, P.J., 1977. C/N ratios in Pacific deep-sea sediments: Effect of inorganic ammonium and organic nitrogen compounds sorbed by clays. Geochimica et Cosmochimica Acta 41: 765–776. Murnane, R.J., Sarmiento, J.L., Bacon, M.P., 1990. Thorium isotopes, particle cycling models, and inverse calculations of model rate constants. Journal of Geophysical Research 95: 16195–16206. Nozaki, Y., Dobashi, F., Kato, Y., Yamamoto, Y., 1998. Distribution of Ra isotopes and the 210Pb and 210Po balance in surface seawaters of the mid Northern Hemisphere. Deep Sea Research I 45: 1263–1284. Nozaki, Y., Yamamoto, Y., 2001. Radium 228 based nitrate fluxes in the eastern Indian Ocean and the South China Sea and a silicon-induced “alkalinity pump” hypothesis. Global Biogeochemical Cycles 15: 555–567. Nozaki, Y., Yang, H.-S., Yamada, M., 1987. Scavenging of thorium in the ocean. Journal of Geophysical Research 92: 772–778. Nyffeler, U.P., Li, Y.-H., Santschi, P.H., 1984. A kinetic approach to describe trace-element distribution between particles and solution in natural aquatic systems. Geochimica et Cosmochimica Acta 48: 1513–1522. Okubo, A., Obata, H., Luo, S., Gamo, T., Yamamoto, Y., Minami, H., Yamada, M., 2007. Particle flux in the twilight zone of the eastern Indian Ocean: A constraint from 234U–230Th and 228Ra–228Th disequilibria. Deep Sea Research I 54: 1758–1772. Otosaka, S., Togawa, O., Baba, M., Karasev, E., Volkov, Y.N., Omata, N., Noriki, S., 2004. Lithogenic flux in the Japan Sea measured with sediment traps. Marine Chemistry 91: 143–163. Owens, S.A., Pike, S., Buesseler, K.O., 2015. Thorium-234 as a tracer of particle dynamics and upper ocean export in the Atlantic Ocean. Deep Sea Research II 116: 42–59. Peterson, M.L., Fabres, J., Wakeham, S.G., Lee, C., Alonso, I.J., Miquel, J.C., 2009. Sampling the vertical particle flux in the upper water column using a large diameter free-drifting NetTrap adapted to an Indented Rotating Sphere sediment trap. Deep Sea Research II 56: 1547–1557. Peterson, M.L., Wakeham, S.G., Lee, C., Askea, M.A., Miquel, J.C., 2005. Novel techniques for collection of sinking particles in the ocean and determining their settling rates. Limnology and Oceanography: Methods 3: 520–532. Quigg, A., Finkel, Z.V., Irwin, A.J., Rosenthal, Y., Ho, T.-Y., Reinfelder, J.R., Schofield, O., Morel, F.M.M., Falkowski, P.G., 2003. The evolutionary inheritance of elemental stoichiometry in marine phytoplankton. Nature 425: 291–294. Ramaswamy, V., Nair, R.R., 1994. Fluxes of material in the Arabian Sea and Bay of Bengal — Sediment trap studies. Proceedings of the Indian Academy of Sciences - Earth and Planetary Sciences 103: 189–210. Roberts, K.A., Xu, C., Hung, C.-C., Conte, M.H., Santschi, P.H., 2009. Scavenging and fractionation of thorium vs. protactinium in the ocean, as determined from particle–water partitioning experiments with sediment trap material from the Gulf of Mexico and Sargasso Sea. Earth and Planetary Science Letters 286: 131–138. Roy-Barman, M., Jeandel, C., Souhaut, M., Rutgers van der Loeff, M., Voege, I., Leblond, N., Freydier, R., 2005. The influence of particle composition on thorium scavenging in the NE Atlantic ocean (POMME experiment). Earth and Planetary Science Letters 240: 681–693. Santschi, P.H., Li, Y.-H., Bell, J., 1979. Natural radionuclides in the water of Narragansett Bay. Earth and Planetary Science Letters 45: 201–213. Santschi, P.H., Murray, J.W., Baskaran, M., Benitez-Nelson, C.R., Guo, L.D., Hung, C.-C., Lamborg, C., Moran, S.B., Passow, U., Roy-Barman, M., 2006. Thorium speciation in seawater. Marine Chemistry 100: 250–268. Sarin, M.M., Krishnaswami, S., Dalai, T.K., Ramaswamy, V., Ittekkot, V., 2000. Settling fluxes of U- and Th-series nuclides in the Bay of Bengal: results from time-series sediment trap studies. Deep Sea Research I 47: 1961–1985. Schmidt, S., 2006. Impact of the Mediterranean Outflow Water on particle dynamics in intermediate waters of the Northeast Atlantic, as revealed by 234Th and 228Th. Marine Chemistry 100: 289–298. Smoak, J.M., Benitez-Nelson, C., Moore, W.S., Thunell, R.C., Astor, Y., Muller-Karger, F., 2004. Radionuclide fluxes and particle scavenging in Cariaco Basin. Continental Shelf Research 24: 1451–1463. Smoak, J.M., Moore, W.S., Thunell, R.C., 2000. Influence of Boundary Scavenging and Sediment Focusing on 234Th, 228Th and 210Pb Fluxes in the Santa Barbara Basin. Estuarine, Coastal and Shelf Science 51: 373–384. Smoak, J.M., Moore, W.S., Thunell, R.C., Shaw, T.J., 1999. Comparison of 234Th, 228Th, and 210Pb fluxes with fluxes of major sediment components in the Guaymas Basin, Gulf of California. Marine Chemistry 65: 177–194. Stavrakakis, S., Chronis, G., Tselepides, A., Heussner, S., Monaco, A., Abassi, A., 2000. Downward fluxes of settling particles in the deep Cretan Sea (NE Mediterranean). Progress in Oceanography 46: 217–240. Stewart, G., Kirk Cochran, J., Xue, J., Lee, C., Wakeham, S.G., Armstrong, R.A., Masqué, P., Carlos Miquel, J., 2007a. Exploring the connection between 210Po and organic matter in the northwestern Mediterranean. Deep Sea Research I 54: 415–427. Stewart, G., Cochran, J.K., Miquel, J.C., Masqué, P., Szlosek, J., Rodriguez y Baena, A.M., Fowler, S.W., Gasser, B., Hirschberg, D.J., 2007b. Comparing POC export from 234Th/238U and 210Po/210Pb disequilibria with estimates from sediment traps in the northwest Mediterranean. Deep Sea Research I 54: 1549–1570. Szlosek, J., Cochran, J.K., Miquel, J.C., Masqué, P., Armstrong, R.A., Fowler, S.W., Gasser, B., Hirschberg, D.J., 2009. Particulate organic carbon–234Th relationships in particles separated by settling velocity in the northwest Mediterranean Sea. Deep Sea Research II 56: 1519–1532. Taguchi, K., Harada, K., Tsunogai, S., 1989. Particulate removal of 230Th and 231Pa in the biologically productive northern North Pacific. Earth and Planetary Science Letters 93: 223–232. Thunell, R.C., Moore, W.S., Dymond, J., Pilskaln, C.H., 1994. Elemental and isotopic fluxes in the Southern California Bight: A time-series sediment trap study in the San Pedro Basin. Journal of Geophysical Research 99: 875–889. Thunell, R.C., Varela, R., Llano, M., Collister, J., -Karger, F.M., Bohrer, R., 2000. Organic carbon fluxes, degradation, and accumulation in an anoxic basin: Sediment trap results from the Cariaco Basin. Limnology and Oceanography 45: 300–308. Tseng, C.-M., Wong, G.T.F., Chou, W.-C., Lee, B.-S., Sheu, D.-D., Liu, K.-K., 2007. Temporal variations in the carbonate system in the upper layer at the SEATS station. Deep Sea Research II 54: 1448–1468. Tseng, C.-M., Wong, G.T.F., Lin, I.-I., Wu, C.-R., Liu, K.-K., 2005. A unique seasonal pattern in phytoplankton biomass in low-latitude waters in the South China Sea. Geophysical Research Letters 32: L08608. Tsunogai, S., Taguchi, K., Harada, K., 1986. Seasonal variation in the difference between observed and calculated particulate fluxes of Th-234 in Funka Bay, Japan. Journal of the Oceanographical Society of Japan 42: 91–98. Tsunogai, S., Uematsu, M., Noriki, S., Tanaka, N., Yamada, M., 1982. Sediment trap experiment in the northern North Pacific: Undulation of settling particles. Geochemical Journal 16: 129–147. Turner, D.., Whitfield, M., Dickson, A., 1981. The equilibrium speciation of dissolved components in freshwater and sea water at 25°C and 1 atm pressure. Geochimica et Cosmochimica Acta 45: 855–881. Volk, T., Hoffert, M.I., 1985. Ocean carbon pumps: Analysis of relative strengths and efficiencies in ocean-driven atmospheric CO2 changes, in: Sundquist, E.T., Broecker, W.S. (Eds.), Geophysical Monograph Series. American Geophysical Union, Washington, D. C., pp. 99–110. Wakeham, S.G., Lee, C., Peterson, M.L., Liu, Z., Szlosek, J., Putnam, I.F., Xue, J., 2009. Organic biomarkers in the twilight zone—Time series and settling velocity sediment traps during MedFlux. Deep Sea Research II 56: 1437–1453. Walsh, I., Dymond, J., Collier, R., 1988. Rates of recycling of biogenic components of settling particles in the ocean derived from sediment trap experiments. Deep Sea Research A 35: 43–58. Wang, W.-L., Armstrong, R.A., Cochran, J.K., Heilbrun, C., 2016. 230Th and 234Th as coupled tracers of particle cycling in the ocean: A maximum likelihood approach. Deep Sea Research I 111: 61–70. Waples, J.T., Benitez-Nelson, C., Savoye, N., Rutgers van der Loeff, M., Baskaran, M., Gustafsson, Ö., 2006. An introduction to the application and future use of 234Th in aquatic systems. Marine Chemistry 100: 166–189. Wei, C.-L., Chen, P.-R., Lin, S.-Y., Sheu, D.D., Wen, L.-S., Chou, W.-C., 2015. Distributions of 210Pb and 210Po in surface water surrounding Taiwan: A synoptic observation. Deep Sea Research II 117: 155–166. Wei, C.-L., Chia, C.-Y., Chou, W.-C., Lee, W.-H., 2016. Sinking fluxes of 210Pb and 210Po in the deep basin of the northern South China Sea. Journal of Environmental Radioactivity. Wei, C.-L., Lin, S.-Y., Sheu, D.D.-D., Chou, W.-C., Yi, M.-C., Santschi, P.H., Wen, L.-S., 2011. Particle-reactive radionuclides (234Th, 210Pb, 210Po) as tracers for the estimation of export production in the South China Sea. Biogeosciences 8: 3793–3808. Wei, C.-L., Murray, J.W., 1991. 234Th/238U disequilibria in the Black Sea. Deep Sea Research I 38: Supplement 2, S855–S873. Wiesner, M.G., Zheng, L., Wong, H.K., Wang, Y., Chen, W., 1996. Fluxes of particulate matter in the South China Sea, in: Ittekkot, V., Schäfer, P., Honjo, S., Depetris, P.J. (Eds.), Particle Flux in the Ocean. Wiley, Chichester, pp. 293–312. Wong, G.T.F., Ku, T.-L., Mulholland, M., Tseng, C.-M., Wang, D.-P., 2007. The SouthEast Asian Time-series Study (SEATS) and the biogeochemistry of the South China Sea—An overview. Deep Sea Research II 54: 1434–1447.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/50322	-
dc.description.abstract	本研究於南海SEATS測站 (18°N, 116°E) 2000 m與3500 m，佈放兩組錨碇式沉降顆粒收集器，進行多年期 (2008~2009年, 2013~2015年) 收集沉降顆粒之實驗，測量沉降顆粒總質量通量 (FMass)、234Th通量 (FTh-234) 與228Th通量 (FTh-228) 的時序變化。兩個深度的FMass時序變化，呈現季節性冬高夏低的循環，與過去在南海的基礎生產力研究結果契合，推測深海收集的顆粒體反應表層海洋基礎生產力的強弱與季節性變化；另外本研究也觀察到FMass有年際之間的差異，各年FMass出現最高值的時間不同。由於部分收集器故障未能收集到沉降顆粒樣品，加上234Th半衰期 (24.1天) 較短，本研究取得之可利用的FTh-234資料點少，有限的資料下顯示FTh-234在兩個深度的變化不大，與同地點測量之透光層中的234Th - 238U不平衡程度，及漂浮式沉降顆粒收集器量得之FTh-234比較，可看出顆粒體在沉降的過程中受分解作用影響，使顆粒體上234Th溶回水體，造成FTh-234隨深度減少之結果。相較於234Th，228Th的半衰期 (1.91年) 和深海顆粒體循環尺度相當，更適合做為探討海洋深層的示蹤劑，由研究前後近三年資料顯示，兩個深度間的FTh-228隨時間變化大，和FMass有些相似，南海沉降顆粒中228Th活度明顯高於其他海域，應受南海西南部寬廣陸棚影響，提供228Th的母核種228Ra來源有關，此外，長期觀測下亦發現南海夏天有低FMass高FTh-228的現象。透過FTh-234、FTh-228與FMass的相關性觀察，234Th與228Th的變化受顆粒垂直通量影響甚大，是釷核種受顆粒體清除作用的明顯證據。本研究亦探討顆粒成分與分佈係數 (Kd) 之關係，與同測站懸浮顆粒，和透光層中利用漂浮式沉降顆粒收集器收集的沉降顆粒比較，本研究量測深海沉降顆粒的Log Kd變化範圍較小，推測可能與深海顆粒組成成分較穩定有關。最後，我們透過234Th/228Th比值關係，減少半衰期時間長度不同造成的影響，以及忽略水體間物理性的傳輸因子，估算南海顆粒的沉降速率，約為168 m d-1，相較於其他海域，顯示南海海域顆粒沉降速率快。本研究於南海深部進行FMass、FTh-234與FTh-228的時序觀測，為深海顆粒通量提供寶貴資料。	zh_TW
dc.description.abstract	Fluxes of total mass (FMass), 234Th (FTh-234) and 228Th (FTh-228) were determined by time-series sediment traps deployed at two depths, 2000 m and 3500 m, at the SEATS (South East Asian Time-series Study, 18°N, 116°E) station in the northern South China Sea (SCS) during June 2008-July 2009 and September 2013-May 2015. The FMass at the two depths showed a synchronized pattern, reflecting the seasonal variability of the primary productivity in the surface water. The FMass also revealed inter-annual variability, which peaked at different time of each year. Due to malfunction of the sediment trap and the short half-life of 234Th (t1/2 = 24.1 days), the FTh-234 data was limited. Combining with the results of 234Th-238U disequilibrium and FTh-234 measured by the floating trap in the euphotic zone, the FTh-234 showed decreasing trend with depth, indicating the decomposition of particles and radioactive decay of 234Th while particles settled through the water column. In contrast to 234Th, due to its longer half-life, 228Th (t1/2 = 1.91 years) is a more suitable tracer for particle scavenging processes in the deep layer. The temporal variation of the FTh-228 was high during the collection period, especially in the summer of 2014. The FTh-228 increases with depth, which indicates that sinking particles continually take up the radionuclide while settling through the water column. It is also found that the specific activity of 228Th in the sinking particles was higher in the SCS than other oceans, which may be caused by higher concentration of its parent radionuclide, 228Ra, released into the seawater from the broad continental shelf of the SCS. Linear correlations between the fluxes of the two radionuclides and the FMass indicate the removal of particle-reactive elements is controlled by the vertical flux of particulate materials in the SCS. Similar Kd values of 234Th of sinking particles in the euphotic zone and deep ocean imply that the composition of settling particles do not change significantly with depth. Sinking velocity of particles, 168 m d-1, was estimated based on the 234Th/228Th ratio. This study is the first data set that provides the temporal observation of fluxes of short-lived thorium isotopes in the deep basin of the SCS.	en
dc.description.provenance	Made available in DSpace on 2021-06-15T12:36:18Z (GMT). No. of bitstreams: 1 ntu-105-R03241403-1.pdf: 2965298 bytes, checksum: 467c0419f6e612effb1d7f48dfce2082 (MD5) Previous issue date: 2016	en
dc.description.tableofcontents	口試委員會審定書 I 誌謝 II 摘要 III Abstract V 目錄 VII 圖目錄 IX 表目錄 X 第一章緒論 1 1.1 海洋中的顆粒體 1 1.2 釷同位素於海洋顆粒研究中的應用與文獻回顧 2 1.2.1 234Th 2 1.2.2 228Th 3 1.2.3 234Th與228Th於南海之研究 4 1.2.4 沉降顆粒與沉降顆粒收集器於南海海域之研究 5 1.3 研究區域 8 1.3.1 南海環境概述 8 1.3.2 東南亞時間序列研究 (SEATS) 8 1.4 研究目的 9 第二章材料與方法 10 2.1 採樣與前置處理 10 2.2 化學分析 12 2.2.1 234Th活度測定 12 2.2.2 228Th活度測定 13 第三章結果 15 3.1 FMass 15 3.2 FTh-234 15 3.3 FTh-228 15 第四章討論 20 4.1 沉降顆粒總質量通量的時序變化 20 4.1.1 FMass的季節變化 20 4.1.2 FMass的垂直變化 22 4.2 釷同位素的時序變化 25 4.2.1 FTh-234的季節變化 25 4.2.2 FTh-228的季節變化 26 4.2.3 FTh-234 / FTh-228比值關係 29 4.3 釷同位素的垂直變化 36 4.3.1 FTh-234的垂直變化 36 4.3.2 FTh-228的垂直變化 37 4.4 其他海域FTh-234與FTh-228 42 4.5 分佈係數 (Kd) 與顆粒成分探討 47 4.6 沉降速率估算 51 第五章結論 56 參考文獻 57 附錄 72
dc.language.iso	zh-TW
dc.subject	SEATS南海時序測站	zh_TW
dc.subject	234Th通量	zh_TW
dc.subject	228Th通量	zh_TW
dc.subject	顆粒清除作用	zh_TW
dc.subject	SEATS南海時序測站	zh_TW
dc.subject	234Th通量	zh_TW
dc.subject	228Th通量	zh_TW
dc.subject	顆粒清除作用	zh_TW
dc.subject	234Th flux	en
dc.subject	SEATS	en
dc.subject	234Th flux	en
dc.subject	228Th flux	en
dc.subject	particle scavenging	en
dc.subject	SEATS	en
dc.subject	228Th flux	en
dc.subject	particle scavenging	en
dc.title	南海深層短半衰期釷放射核種的沉降通量時序變化	zh_TW
dc.title	Sinking Fluxes of Short-lived Thorium Radionuclides in the Deep Basin of the South China Sea	en
dc.type	Thesis
dc.date.schoolyear	104-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	周文臣,林卉婷
dc.subject.keyword	SEATS南海時序測站,234Th通量,228Th通量,顆粒清除作用,	zh_TW
dc.subject.keyword	SEATS,234Th flux,228Th flux,particle scavenging,	en
dc.relation.page	76
dc.identifier.doi	10.6342/NTU201601645
dc.rights.note	有償授權
dc.date.accepted	2016-08-01
dc.contributor.author-college	理學院	zh_TW
dc.contributor.author-dept	海洋研究所	zh_TW
顯示於系所單位：	海洋研究所

文件中的檔案：

檔案	大小	格式
ntu-105-1.pdf 未授權公開取用	2.9 MB	Adobe PDF

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。