N. Gruber et al., Spatiotemporal patterns of carbon-13 in the global surface oceans and the oceanic Suess effect, GLOBAL BIOG, 13(2), 1999, pp. 307-335
A global synthesis of the C-13/C-12 ratio of dissolved inorganic carbon (DI
C) in the surface ocean is attempted by summarizing high-precision data obt
ained from 1978 to 1997 in all major ocean basins. The data, mainly along t
ransects but including three subtropical time series, are accompanied by si
multaneous, precise measurements of DIC concentration and titration alkalin
ity. The reduced isotopic ratio, delta(13)C, in the surface ocean water is
governed by a balance between biological and thermodynamic processes. These
processes have strongly opposing tendencies, which result in a complex spa
tial pattern in delta(13)C with relatively little variability. The most dis
tinctive feature in the spatial distribution of delta(13)C seen in our data
is a maximum of delta(13)C near the subantarctic front with sharply fallin
g values to the south. We attribute this feature to a combination of biolog
ical uptake of CO2 depleted in C-13 (low delta(13)C) and air-sea exchange n
ear the front and upwelling further south of waters with low delta(13)C res
ulting from the remineralization of organic matter. Additional features are
maxima in delta(13)C downstream of upwelling regions, reflecting biologica
l uptake, and minima in the subtropical gyres caused by strongly temperatur
e dependent thermodynamic isotopic fractionation. At the time series statio
ns, two in the North Atlantic Ocean and one in the North Pacific, distinct
seasonal cycles in delta(13)C are observed, the Pacific data exhibiting onl
y about half the amplitude of the Atlantic. Secular decreases in delta(13)C
caused by the invasion of isotopically light anthropogenic CO2 into the oc
ean (the C-13 Suess effect) have been identified at these time series stati
ons and also in data from repeated transects in the Indian Ocean and the tr
opical Pacific. A tentative global extrapolation of these secular decreases
yields a surface oceanic C-13 Suess effect of approximately -0.018 parts p
er thousand yr(-1) from 1980 to 1995. This effect is nearly the same as the
C-13 Suess effect observed globally in the atmosphere over the same period
. We attribute this response to a deceleration in the growth rate of anthro
pogenic CO2 emissions after 1979, which subsequently has reduced the atmosp
heric C-13 Suess effect more than the surface ocean effect.