The Si-32 Paradox is that the GEOSECS measurements of Si-32 specific activi
ty in silica collected on ferric hydroxide-coated fibers are essentially un
iform throughout the deep water of the global oceans [Somayajulu et al., Ea
rth Planet. Sci, Lett. 85 (1987) 329-342; 107 (1991) 197-216]. Peng, Maier-
Reimer, and Broecker have argued that Si-32 specific activities in Indian a
nd Pacific deep water should be 3-5 times lower than in the deep Atlantic,
because the dissolved SiO2 concentrations are higher than in the Atlantic b
y this factor, and because cosmogenic Si-32 should be essentially confined
to the ocean basins in which it falls due to its short half-life relative t
o mixing times for water interchange between the oceans. Thus these authors
proposed that the entire GEOSECS Si-32 data set "may be flawed". The resol
ution of the Si-32 Paradox is straightforward. Silica collected on the acri
lan fibers is a two-phase mixture of biogenic particulate SiO2 (opaline tes
ts of diatoms and radiolaria) and silica scavenged chemically from dissolve
d SiO2 in ocean water. Particulate silica is the high-activity component in
this mixture, and dissolved SiO2 is the low-activity end-member. Thus the
mixing trajectories on 'Cornucopia plots' of specific activity vs, reciproc
al SiO2 recovered weights overlap in specific-activity range, regardless of
the different concentrations and specific activities of dissolved silica i
n the deep waters. The specific activities of dissolved SiO2 in the Pacific
, Indian, and Atlantic oceans, as deciphered from the two-component total a
ctivity data, are similar to 0, 2.6, and 4.5 dpm/kg SiO2, The atmospheric p
roduction rate of Si-32 has been calculated and is found to be 0.72 atoms/m
(2) s. This value is much lower than in previous calculations, which were b
ased on the Lal and Peters plots of stratospheric fallout that incorrectly
use geomagnetic latitude for scaling the fallout patterns. Correcting these
curves to scale by geographic latitude, which controls the stratospheric '
dumping' pattern, we show that the Si-32 concentrations in Indian rains rep
resent the total fallout from both stratosphere and troposphere, rather tha
n only tropospheric fallout as was previously assumed. The new value of the
atmospheric production rate is consistent with the low activities of the d
issolved silica in the three oceans, which are modulated to some extent by
radioactive decay of Si-32 during the sequestering of particulate silica in
sediments before regeneration in bottom waters, (C) 2000 Elsevier Science
B.V. All rights reserved.