The influence of surface state and saturation state on the dissolution kinetics of biogenic aragonite in seawater
Journal Article
·
· American Journal of Science; (USA)
- Univ. of South Florida, St. Petersburg (USA)
Laboratory observations of aragonite dissolution in seawater, under temperature and pressure conditions that approximate the natural oceanic environment, indicate that R = k{prime}((CO{sup 2{minus}}{sub 3}){sub s} - (CO{sup 2{minus}}{sub 3})){sup n} is an appropriate expression describing the dependence of dissolution rate on seawater saturation, state, where R is aragonite dissolution rate in percent per day, (CO{sup 2{minus}}{sub 3}){sub s} is the carbonate ion concentration at saturation, and (CO{sup 2{minus}}{sub 3}) is the in-situ carbonate ion concentration. Under conditions in which the influence of surface alteration is minimized, plots of dissolution rate, R, versus ((CO{sup 2{minus}}{sub 3}){sub s} - (CO{sup 2{minus}}{sub 3})) approach linearity. Consequently, in the absence of surface alteration effects, our results suggest that the reaction order, n, in the above expression should be equal to one. Use of single pteropod shells in extended experimental sequences indicates that progressive roughening of the shell surface by dissolution can substantially enhance shell dissolution rates. Surface alteration leads to variable values of the rate constant, k{prime}, in the expression above. For rate measurements obtained at increasing degrees of both undersaturation and shell roughness, the multiplicative factors k{prime} and ((CO{sup 2{minus}}{sub 3}){sub s} - (CO{sup 2{minus}}{sub 3})) give rise to curvature in plots of rate versus ((CO{sup 2{minus}}{sub 3}){sub s} - (CO{sup 2{minus}}{sub 3})). For models in which variations in k{prime} are not explicitly acknowledged, dissolution rates are generally described successfully with reaction orders (n) greater than one. Our experiments, performed at variable pressure, were modeled using several realistic partial molar volume changes ({delta} V) for aragonite dissolution in seawater.
- OSTI ID:
- 6652129
- Journal Information:
- American Journal of Science; (USA), Journal Name: American Journal of Science; (USA) Vol. 289:9; ISSN 0002-9599; ISSN AJSCA
- Country of Publication:
- United States
- Language:
- English
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Related Subjects
54 ENVIRONMENTAL SCIENCES
540320* -- Environment
Aquatic-- Chemicals Monitoring & Transport-- (1990-)
ALKALINE EARTH METAL COMPOUNDS
AQUATIC ORGANISMS
ARAGONITE
CALCIUM CARBONATES
CALCIUM COMPOUNDS
CARBON COMPOUNDS
CARBONATE MINERALS
CARBONATES
CHEMISTRY
DISSOLUTION
HYDROGEN COMPOUNDS
MINERALS
OXYGEN COMPOUNDS
PLANKTON
SEAWATER
SEDIMENTS
THERMODYNAMICS
WATER
WATER CHEMISTRY
540320* -- Environment
Aquatic-- Chemicals Monitoring & Transport-- (1990-)
ALKALINE EARTH METAL COMPOUNDS
AQUATIC ORGANISMS
ARAGONITE
CALCIUM CARBONATES
CALCIUM COMPOUNDS
CARBON COMPOUNDS
CARBONATE MINERALS
CARBONATES
CHEMISTRY
DISSOLUTION
HYDROGEN COMPOUNDS
MINERALS
OXYGEN COMPOUNDS
PLANKTON
SEAWATER
SEDIMENTS
THERMODYNAMICS
WATER
WATER CHEMISTRY