Bahamas Sclerosponge Stable Isotope Data
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               World Data Center for Paleoclimatology, Boulder
                                  and
                     NOAA Paleoclimatology Program
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NOTE: PLEASE CITE CONTRIBUTORS WHEN USING THIS DATA!!!!!


NAME OF DATA SET: Bahamas Sclerosponge Stable Isotope Data
LAST UPDATE: 8/2004 (Original receipt by WDC Paleo)


CONTRIBUTOR: Peter Swart, University of Miami
IGBP PAGES/WDCA CONTRIBUTION SERIES NUMBER: 2004-051


SUGGESTED DATA CITATION: Swart, P.K., et al. 2004. 
Bahamas Sclerosponge Stable Isotope Data. 
IGBP PAGES/World Data Center for Paleoclimatology 
Data Contribution Series # 2004-051.
NOAA/NGDC Paleoclimatology Program, Boulder CO, USA.


ORIGINAL REFERENCE: Swart, P.K., S. Torrold, A. Esienhauer, B. Rosenheim,
C.G.A. Harrison, M. Grammer, and C. Latkoczy. 2002. 
Intra-annual variation in the stable oxygen and carbon and trace element 
composition of sclerosponges.
Paleoceanography 17(3), 1029/2000PA000622.



ABSTRACT:
This paper presents data to support the presence of 
(i) intra-annual signals in the chemical composition of the skeletons 
of sclerosponges from the Bahamas, and 
(ii) variable rates of skeletal accretion. These conclusions are based 
on data obtained by using a microsampling method for the stable oxygen 
and carbon isotopes in which material was extracted at a resolution of 
one sample every 32 mm and a laser microprobe which obtained trace 
element data every 20 mm (Sr, Mg, and Pb). An age model was established 
using a combination of U-Th dating, changes in the concentration of Pb, 
and the change in the d13C of the skeleton of the sclerosponges. 
These methods yield a mean growth rate of 220 mm/yr, but suggest 
that the growth rate in this particular sclerosponge was in fact 
not constant and varied between 100 and 400 mm/yr. The variable 
growth rate was confirmed through spectral analysis of the d18O and 
Sr/Ca data that showed peaks corresponding to the annual cycle 
in these parameters as well as peaks corresponding to growth rates 
of approximately 128, 212, 270, and 400 mm/yr. The presence of these 
additional frequencies suggests a growth rate between approximately 
100 and 400  mm/yr. These conclusions were supported by modeling of 
oxygen isotopic data measured on a scleractinian coral as well as 
model isotope data generated on synthetic time series. These findings 
have important implications for the use of sclerosponges as proxies 
of paleoclimate, because they emphasize the need for a precise 
yearly chronology in order that proxy data can be compared  
with climatic variables such as the North Atlantic Oscillation or 
the Atlantic Multidecadal Oscillation.


GEOGRAPHIC REGION: Bahamas, Western Atlantic
PERIOD OF RECORD: 1885 - 1992


DESCRIPTION: 
Bahamas Sclerosponge Stable Isotope Data

These data are indexed to the U/Th constant growth rate age model 
described in Swart et al., 2002.

Site: Tongue of the Ocean (TOTO), Bahamas   
23 55' North
76 50' West
146 m. water depth


DATA:

Year     d13C     d18O
1992     3.76     0.56
1991     3.91     0.38
1990     3.92     0.42
1989      3.9     0.45
1988     4.09     0.53
1987     4.08     0.52
1986        4     0.26
1985     4.07     0.57
1984     4.29      0.6
1983     4.27     0.42
1982     4.23     0.22
1981     4.08     0.29
1980     4.06     0.45
1979     3.75     0.53
1978     3.96     0.58
1977      3.9      0.2
1976     3.62    -0.15
1975     3.89     0.07
1974     4.08     0.22
1973     4.21     0.32
1972     4.38     0.47
1971     4.21     0.25
1970     4.02     0.22
1969     3.87     0.15
1968     3.94     0.21
1967     4.03     0.27
1966     4.05     0.41
1965     4.11     0.69
1964     4.03     0.31
1963     4.22     0.48
1962      4.1     0.31
1961     4.31     0.39
1960     4.24     0.17
1959     4.18     0.41
1958     4.38     0.54
1957     4.45     0.63
1956     4.37     0.59
1955     4.01     0.15
1954     4.03     0.33
1953     3.92    -0.02
1952     4.03     0.06
1951     3.93    -0.18
1950     3.85    -0.26
1949     4.02     0.04
1948     4.16     0.32
1947     4.09     0.25
1946     4.01      0.1
1945     4.24     0.22
1944     4.24     0.25
1943     4.55     0.35
1942     4.59      0.4
1941     4.69     0.55
1940     4.76     0.54
1939     4.54     0.25
1938     4.35     0.48
1937     4.54     0.68
1936     4.48     0.59
1935     4.58     0.75
1934     4.72     0.86
1933     4.45      0.6
1932     4.43     0.51
1931     4.56     0.55
1930     4.55     0.52
1929     4.54     0.44
1928      4.6      0.6
1927     4.59     0.55
1926     4.64     0.57
1925     4.64     0.52
1924     4.61     0.48
1923     4.74     0.43
1922     4.44     0.47
1921     4.57      0.4
1920     4.56     0.33
1919     4.49     0.42
1918     4.62     0.71
1917      4.6     0.72
1916      4.6     0.77
1915     4.62     0.75
1914     4.53     0.58
1913     4.53     0.61
1912     4.49     0.58
1911     4.59     0.65
1910     4.68     0.67
1909     4.69     0.45
1908     4.47    -0.15
1907     4.83     0.39
1906     4.63     0.44
1905     4.85     0.54
1904     4.74     0.29
1903     4.72     0.14
1902     4.66     0.13
1901     4.66     0.38
1900      4.7     0.36
1899     4.69     0.32
1898     4.65     0.23
1897     4.66     0.35
1896     4.66      0.4
1895     4.62     0.39
1894     4.82     0.38
1893     4.75     0.32
1892     4.68     0.06
1891     4.67     0.33
1890      4.7     0.36
1889     4.68     0.32
1888     4.64     0.26
1887     4.67     0.42
1886     4.65     0.42
1885      4.6     0.35