The Marine Carbonate System: Ionic Interactions and Biogeochemical Processes
Abstract
The absorption of atmospheric carbon dioxide (CO2) by seawater and subsequent
equilibrium reactions within this ionic medium give rise to a complex chemical
system often referred to as the marine carbonate system. This system is influenced by
physical and biogeochemical processes in the ocean. The marine carbonate system is
a major component of the global carbon cycle and is, by virtue of its interaction with
atmospheric CO2, of fundamental importance to the Earth’s climate. Accurate
knowledge of the properties of the marine carbonate system is a prerequisite for
understanding the chemical forcing and consequences of key biogeochemical
processes such as biological production, organic matter respiration, or uptake of
anthropogenic carbon. The assessment of the marine carbonate system builds on
precise measurements by state-of-the-art analytical methods as well as an
understanding of the underlying fundamental chemistry in terms of ionic interactions
and equilibrium thermodynamics. This thesis focuses on different aspects of the
marine carbonate system with emphasis on biogeochemical processes and
thermodynamic modelling of the seawater ionic medium. A quantitative
understanding of the equilibrium solution chemistry of seawater ultimately relies on
accurate estimations of activity coefficients of all the various components that make
up the solution. Activity coefficients of the carbonate system in sodium chloride
solution of varying ionic strength were estimated by Monte Carlo simulations at
different temperatures, as well as activity coefficients of chloride and sulfate salts of a
simplified seawater electrolyte, suggesting that a complete Monte Carlo description of
seawater activity coefficients may be achievable using the hard sphere approach with
a very limited number of fitted parameters. Chemical speciation modelling showed
that the measured excess alkalinity of Baltic seawater is consistent with an organic
alkalinity derived from humic substances of terrestrial origin. In deep waters of the
Baltic Sea, oxygen and sulfate was found to be the major electron acceptors to the
remineralization of organic matter under different redox conditions. It was further
suggested that this organic matter predominantly had a terrestrial origin. The
subsurface waters of the central Arctic Ocean were found to be a sink of
anthropogenic CO2, attributed to uptake by source waters of Atlantic origin. The seaice
covered central Arctic Ocean was also shown to harbor low, but significant
biological productivity. Late summer net community production was estimated using
multiple approaches based on both discrete and underway measurements and results
showed large spatial variability between the deep basins with extremes at the marginal
ice zone.
Parts of work
I. Ulfsbo, A., Hulth, S., Anderson, L. G. (2011), pH and biogeochemical processes
in the Gotland Basin of the Baltic Sea, Marine Chemistry, 127, 20-30.
::doi::10.1016/j.marchem.2011.07.004 II. Abbas, Z., Ulfsbo, A., Turner, D. R. (2013). Monte Carlo simulation of the dissociation
constants of CO2 in 0 to 1 molal sodium chloride between 0 and 25 C,
Marine Chemistry, 150, 1-10. ::doi::10.1016/j.marchem.2013.01.002 III. Ulfsbo, A., Cassar, N., Korhonen, M., van Heuven, S., Hoppema, M., Kattner, G.,
Anderson, L. G. (2014). Late summer net community production in the central
Arctic Ocean using multiple approaches, Global Biogeochemical Cycles, submitted
February 2014. IV. Ericson, Y., Ulfsbo, A., van Heuven, S., Kattner, G., Anderson, L. G. (2014). Increasing
carbon inventory of the intermediate layers of the Arctic Ocean, Journal
of Geophysical Research: Oceans. ::doi::10.1002/2013JC009514 V. Ulfsbo, A., Kulinski, K., Anderson, L. G., Turner, D.R. (2014). Modelling organic
alkalinity in the Baltic Sea using a Humic-Pitzer approach, manuscript in
preparation for Marine Chemistry. VI. Ulfsbo, A., Abbas, Z., Turner, D. R. (2014). Activity coefficients of a simplified
seawater electrolyte at varying salinity (5-40) and temperature (0-25 C) using
Monte Carlo simulations, manuscript in preparation for Marine Chemistry.
Degree
Doctor of Philosophy
University
University of Gothenburg. Faculty of Science
Institution
Department of Chemistry and Molecular Biology ; Institutionen för kemi och molekylärbiologi
Disputation
Onsdagen den 28 maj 2014, kl. 10.00, Sal KB, Kemigården 4
Date of defence
2014-05-28
ulfsbo@chem.gu.se
Date
2014-05-07Author
Ulfsbo, Adam
Keywords
Marine
seawater
carbonate system
CO2
Arctic Ocean
Baltic Sea
organic alkalinity
Pitzer
Monte Carlo
activity coefficients
biogeochemical processes
Publication type
Doctoral thesis
ISBN
978-91-628-8998-2
Language
eng