Calcification depth of deep-dwelling planktonic foraminifera from the eastern North Atlantic constrained by stable oxygen isotope ratios of shells from stratified plankton tows
A. Rebotim, A. Voelker, L. Jonkers, J. Waniek, M. Schulz, M. Kučera
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引用次数: 9
Abstract
Abstract. Stable oxygen isotopes (δ18O) of planktonic foraminifera are
one of the most used tools to reconstruct environmental conditions of the
water column. Since different species live and calcify at different depths
in the water column, the δ18O of sedimentary foraminifera
reflects to a large degree the vertical habitat and interspecies δ18O differences and can thus potentially provide information on the
vertical structure of the water column. However, to fully unlock the
potential of foraminifera as recorders of past surface water properties, it
is necessary to understand how and under what conditions the environmental
signal is incorporated into the calcite shells of individual species.
Deep-dwelling species play a particularly important role in this context
since their calcification depth reaches below the surface mixed layer. Here
we report δ18O measurements made on four deep-dwelling
Globorotalia species collected with stratified plankton tows in the eastern North
Atlantic. Size and crust effects on the δ18O signal were
evaluated showing that a larger size increases the δ18O of G. inflata and
G. hirsuta, and a crust effect is reflected in a higher δ18O signal in G. truncatulinoides. The great
majority of the δ18O values can be explained without invoking
disequilibrium calcification. When interpreted in this way the data imply
depth-integrated calcification with progressive addition of calcite with
depth to about 300 m for G. inflata and to about 500 m for G. hirsuta. In G. scitula, despite a strong
subsurface maximum in abundance, the vertical δ18O profile is
flat and appears dominated by a surface layer signal. In G. truncatulinoides, the δ18O profile follows equilibrium for each depth, implying a constant
habitat during growth at each depth layer. The δ18O values are
more consistent with the predictions of the Shackleton (1974)
palaeotemperature equation, except in G. scitula which shows values more consistent
with the Kim and O'Neil (1997) prediction. In all cases, we observe a
difference between the level where most of the specimens were present and
the depth where most of their shell appears to calcify.
期刊介绍:
The Journal of Micropalaeontology (JM) is an established international journal covering all aspects of microfossils and their application to both applied studies and basic research. In particular we welcome submissions relating to microfossils and their application to palaeoceanography, palaeoclimatology, palaeobiology, evolution, taxonomy, environmental change and molecular phylogeny.