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Thorium and uranium isotopes in a manganese nodule from the Peru basin determined by alpha spectrometry and thermal ionization mass spectrometry (TIMS): Are manganese supply and growth related to climate?

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Abstract

Thorium- and uranium isotopes were measured in a diagenetic manganese nodule from the Peru basin applying alpha- and thermal ionization mass spectrometry (TIMS). Alpha-counting of 62 samples was carried out with a depth resolution of 0.4 mm to gain a high-resolution230Thexcess profile. In addition, 17 samples were measured with TIMS to obtain precise isotope concentrations and isotope ratios. We got values of 0.06–0.59 ppb (230Th), 0.43–1.40 ppm (232Th), 0.09–0.49 ppb (234U) and 1.66–8.24 ppm (238U). The uranium activity ratio in the uppermost samples (1–6 mm) and in two further sections in the nodule at 12.5±1.0 mm and 27.3–33.5 mm comes close to the present ocean water value of 1.144±0.004. In two other sections of the nodule, this ratio is significantly higher, probably reflecting incorporation of diagenetic uranium. The upper 25 mm section of the Mn nodule shows a relatively smooth exponential decrease in the230Thexcess concentration (TIMS). The slope of the best fit yields a growth rate of 110 mm/Ma up to 24.5 mm depth. The section from 25 to 30.3 mm depth shows constant230Thexcess concentrations probably due to growth rates even faster than those in the top section of the nodule. From 33 to 50 mm depth, the growth rate is approximately 60 mm/Ma. Two layers in the nodule with distinct laminations (11–15 and 28–33 mm depth) probably formed during the transition from isotopic stage 8 to 7 and in stage 5e, respectively. The Mn/Fe ratio shows higher values during interglacials 5 and 7, and lower ones during glacials 4 and 6. A comparison of our data with data from adjacent sediment cores suggests (a) a variable supply of hydrothermal Mn to sediments and Mn nodules of the Peru basin or (b) suboxic conditions at the water sediment interface during periods with lower Mn/Fe ratios.

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References

  • Berger WH, Finkel RC, Killingley JS, Marchig V (1983) Glacial-Holocene transition in deep sea sediments: Manganese spike in the East-Equatorial Pacific. Nature 303:231–233

    Google Scholar 

  • Berner RA (1980) Early diagenesis. A theoretical approach. Princeton University Press, Princeton, New Jersey

    Google Scholar 

  • Bischoff JL, Piper DZ (eds) (1979) Marine geology and oceanography of the Pacific manganese nodule province. Marine science, vol 9. Plenum Press, New York

    Google Scholar 

  • Boudreau BP, Scott MR (1978) A model for the diffusion-controlled growth of deep-sea manganese nodules. Am J Sci 278:903–929

    Google Scholar 

  • Broecker WS, Peng TH (1982) Tracers in the sea. A publication of the Lamont-Doherty Geological Observatory, Columbia University, Palisades, New York.

    Google Scholar 

  • Calvert SE, Piper DZ (1984) Geochemistry of ferromanganese nodules from domes site A, northern equatorial Pacific: multiple diagenetic metal sources in the deep sea. Geochim Cosmochim Acta 48:1913–1928

    Google Scholar 

  • Chabaux F, Cohen AS, O’Nions RK, Hein JR (1995)238U-234U-230Th chronometry of Fe-Mn crusts: growth processes and recovery of thorium isotopic ratios of seawater. Geochim Cosmochim Acta 59:633–638

    Article  Google Scholar 

  • Chen JH, Edwards RL, Wasserburg GJ (1986)238U,234U, and232Th in seawater. Earth Planet Sci Lett 80:241–251

    Article  Google Scholar 

  • Chester R, Aston SR (1976) The geochemistry of deep sea sediments. In: Riley JP, Chester R (eds) Chemical oceanography, vol. 6. Academic Press, New York

    Google Scholar 

  • Dymond J, Lyle M, Finney B, Piper DZ, Murphy K, Conard R, Pisias N (1984) Ferromanganese nodules from MANOP site H, S, and R-control of mineralogical and chemical composition by multiple accretionary processes. Geochim Cosmochim Acta 48:931–949

    Article  Google Scholar 

  • Edwards RL, Chen JH, Wasserburg GJ (1987)238U-234U-230Th and232Th systematics and the precise measurements of time over the past 500 000 years. Earth Planet Sci Lett 81:175–192

    Google Scholar 

  • Edwards RL, Beck JW, Burr GS, Donahue DJ, Chappel JMA, Bloom AL, Druffel ERM, Taylor FW (1993) A large drop in atmospheric14C/12C and reduced melting in the younger dryas, documented with230Th ages of corals. Science 260:962–967

    Google Scholar 

  • Eisenhauer A, Gögen K, Pernicka E, Mangini A (1992) Climatic influences on the growth rates of Mn crusts during the Late Quaternary. Earth Planet Sci Lett 109:25–36

    Article  Google Scholar 

  • Finney BP, Heath GR, Lyle M (1984) Growth rates of mangneserich nodules at MANOP site H (eastern North Pacific). Geochim Cosmochim Acta 48:911–919

    Article  Google Scholar 

  • Finney BP, Lyle MW, Heath GR (1988) Sedimentation at MANOP site H (eastern equatorial Pacific) over the Past 400 000 years: climatically induced redox variations and their effects on transition metal cycling. Paleoceanography 3:169–189

    Google Scholar 

  • Froelich PN, Klinkhammer GP, Bender ML, Luedtke NA, Heath GR, Cullen D, Dauphin P, Hammond D, Hartmann B, Maynard V (1979) Early oxidation of organic matter in pelagic sediments of the eastern equatorial Atlantic: suboxic diagenesis. Geochim Cosmochim Acta 43:1075–1090

    Article  Google Scholar 

  • Halbach P, Puteanus D (1988) Geochemical trends of different genetic types of nodules and crusts. In: Halbach P, Friedrich G, Stackelberg U von (eds) The manganese nodule belt of the Pacific Ocean. Geological environment, nodule formation, and mining aspects. Ferdinand Enke Verlag, Stuttgart, pp 61–69

    Google Scholar 

  • Halbach P, Friedrich G, Stackelberg U von (eds) (1988) The manganese nodule belt of the Pacific Ocean. Geological environment, nodule formation, and mining aspects. Ferdinand Enke Verlag, Stuttgart

    Google Scholar 

  • Holland HD (1984) The chemical evolution of the atmosphere and oceans. Princeton University Press, Princeton, New Jersey

    Google Scholar 

  • Huh CA, Ku TL (1984) Radiochemical observations on manganese nodules from three sedimentary environments in the North Pacific. Geochim Cosmochim Acta 48:951–963

    Google Scholar 

  • Krishnaswami S, Mangini A, Thomas JH, Sharma P, Cochran JK, Turekian KK, Parker PD (1982)10Be and Th isotopes in manganese nodules and adjacent sediments: nodule growth histories and nuclide behavior. Earth Planet Sci Lett 59:217–234

    Article  Google Scholar 

  • Ku TL, Broecker WS (1967) Uranium, thorium and protactinium in an Mn nodule. Earth Planet Sci Lett 2:317–320

    Article  Google Scholar 

  • Leinen M, Pisias N (1984) An objective technique for determining end-member compositions and for partitioning sediments according to their sources. Geochim Cosmochim Acta 48:47–62

    Article  Google Scholar 

  • Lyle M (1981) Formation and growth of ferromanganese oxides on the Nazca plate. Geol Soc Am Mem 154:269–295

    Google Scholar 

  • Lyle M, Heath RG, Pisias NG (1979) Sedimentation at MANOP site S, 11°N, 140 W, Central Pacific Ocean. EOS 60:850

    Google Scholar 

  • Mangini A (1988) Ages and growth rates of Mn nodules and crusts. In: Halbach P, Friedrich G, Stackelberg U von (eds) The manganese nodule belt of the Pacific Ocean. Geological environment, nodule formation, and mining aspects. Ferdinand Enke Verlag, Stuttgart, pp 142–151

    Google Scholar 

  • Mangini A, Eisenhauer A, Walter P (1990) Response of manganese in the ocean to the climatic cycles in the Quaternary. Paleoceanography 5:811–821

    Google Scholar 

  • Mangini A, Rutsch HJ, Frank M, Eisenhauer A, Eckhardt JD (1994) Is there a relationship between atmospheric CO2 and manganese in the ocean? NATO ASI Ser 117:87–104

    Google Scholar 

  • Martinson DG, Pisias NG, Hays JD, Imbrie J, Moore TC Jr, Shackleton NJ (1987) Age dating and the orbital theory of the Ice Ages: development of a high-resolution 0 to 300 000-year chronostratigraphy. Quaternary Res 27:1–29

    Article  Google Scholar 

  • Puteanus D, Glasby GP, Stoffers P, Mangini A, Kunzendorf H (1989) Distribution, internal structure and composition of manganese crusts from the seamounts east of the Teahitio-Mehetia Hot Spot, Southwest Pacific. Marine Mining 8:245–266

    Google Scholar 

  • Reyss JL, Marchig V, Ku T (1982) Rapid growth of a deep-sea manganese nodule. Nature 295:401–403

    Article  Google Scholar 

  • Schmitz W (1985) Sedimentverteilung und Akkumulationsraten im S.W. Pazifischen Becken (Transekt Tahiti — Ostpazifischer Rücken — Neuseeland, entlang 42°S). Dissertation, Universität Heidelberg

  • Segl M, Mangini A, Beer J, Bonani G, Suter M, Wölfli W (1989) Growth rate variations of manganese nodules and crusts induced by paleoceanographic events. Paleoceanography 4:511–530

    Google Scholar 

  • Stackelberg U von (1988) Principles of nodule field formation. In: Halbach P, Friedrich G, Stackelberg U von (eds) The manganese nodule belt of the Pacific Ocean. Geological environment, nodule formation, and mining aspects. Ferdinand Enke Verlag, Stuttgart, pp 159–166

    Google Scholar 

  • Stoffers P, Sioulas A, Glasby GP, Schmitz W, Mangini A (1984) Sediments and micronodules in the Northern and Central Peru Basin. Geol Rundschau 73:1055–1080

    Article  Google Scholar 

  • Walter P, Stoffers P (1985) Chemical characteristics of metalliferous sediments from eight areas on the Galapagos Rift and East Pacific Rise between 2°N and 42°S. Mar Geol 65:271–287

    Article  Google Scholar 

  • Weiss RF (1977) Hydrothermal manganese in the deep sea: scavenging, residence time, and Mn/3He Relationships. Earth Planet Sci Lett 37:257–262

    Article  Google Scholar 

Download references

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  1. Heidelberger Akademie der Wissenschaften, c/o Institut für Umweltphysik, INF 366, D-69120, Heidelberg, Germany

    A. Bollhöfer, A. Eisenhauer, N. Frank, D. Pech & A. Mangini

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  1. A. Bollhöfer
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  2. A. Eisenhauer
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  3. N. Frank
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  4. D. Pech
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  5. A. Mangini
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Bollhöfer, A., Eisenhauer, A., Frank, N. et al. Thorium and uranium isotopes in a manganese nodule from the Peru basin determined by alpha spectrometry and thermal ionization mass spectrometry (TIMS): Are manganese supply and growth related to climate?. Geol Rundsch 85, 577–585 (1996). https://doi.org/10.1007/BF02369012

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