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Ocean alkalinity, buffering and biogeochemical processes
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Alkalinity, the excess of proton acceptors over donors, plays a major
role in ocean chemistry, in buffering and in calcium carbonate
precipitation and dissolution. Understanding alkalinity dynamics is
pivotal to quantify ocean carbon dioxide uptake during times of global
change. Here we review ocean alkalinity and its role in ocean buffering
as well as the biogeochemical processes governing alkalinity and pH in
the ocean. We show that it is important to distinguish between
measurable titration alkalinity and charge-balance alkalinity that is
used to quantify calcification and carbonate dissolution and needed to
understand the impact of biogeochemical processes on components of the
carbon dioxide system. A general treatment of ocean buffering and
quantification via sensitivity factors is presented and used to link
existing buffer and sensitivity factors. The impact of individual
biogeochemical processes on ocean alkalinity and pH is discussed and
quantified using these sensitivity factors. Processes governing ocean
alkalinity on longer time scales such as carbonate compensation,
(reversed) silicate weathering and anaerobic mineralization are
discussed and used to derive a close-to-balance ocean alkalinity budget
for the modern ocean.
Title: Ocean alkalinity, buffering and biogeochemical processes
Description:
Alkalinity, the excess of proton acceptors over donors, plays a major
role in ocean chemistry, in buffering and in calcium carbonate
precipitation and dissolution.
Understanding alkalinity dynamics is
pivotal to quantify ocean carbon dioxide uptake during times of global
change.
Here we review ocean alkalinity and its role in ocean buffering
as well as the biogeochemical processes governing alkalinity and pH in
the ocean.
We show that it is important to distinguish between
measurable titration alkalinity and charge-balance alkalinity that is
used to quantify calcification and carbonate dissolution and needed to
understand the impact of biogeochemical processes on components of the
carbon dioxide system.
A general treatment of ocean buffering and
quantification via sensitivity factors is presented and used to link
existing buffer and sensitivity factors.
The impact of individual
biogeochemical processes on ocean alkalinity and pH is discussed and
quantified using these sensitivity factors.
Processes governing ocean
alkalinity on longer time scales such as carbonate compensation,
(reversed) silicate weathering and anaerobic mineralization are
discussed and used to derive a close-to-balance ocean alkalinity budget
for the modern ocean.
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