INTRODUCTION
THE NEED FOR ECOSYSTEM CARBON
MANAGEMENT
The earth’s climate is crucially dependent on the composition of the atmosphere, and in
particular on the concentration in it of greenhouse gases that increase the amount of the
sun’s heat that is retained. The two most important of these are carbon dioxide (CO
2
) and
methane (CH4). Both gases are naturally present in the atmosphere as part of the carbon
cycle but their concentration has been greatly increased by human activities, particularly
since industrialisation. There is more carbon dioxide in the atmosphere now than at any
time in the past 650,000 years. In 2006 the global average atmospheric concentration of
CO
2
was 381 parts per million (ppm), compared with 280 ppm at the start of the industrial
revolution in about 1750. The rate at which the concentration is increasing is the highest
since the beginning of continuous monitoring in 1959 (Canadell et al. 2007).
The Intergovernmental Panel on Climate Change (IPCC) has
Note on units and quantities
stated that limiting global temperature increase to 2–2.4°C
1 gigaton of carbon (Gt C) = 10
9
tonnes of carbon (t C).
and thereby staving off the worst effects of climate change re-
Carbon (C) or carbon dioxide (CO
2
)? It is when carbon is
quires greenhouse gas concentrations in the atmosphere to be
in the form of carbon dioxide gas in the atmosphere that
stabilised at 445–490 ppm CO
2
equivalent (see box) or lower
it has its effect on climate change. However, as it is the
(IPCC 2007b). As there is presently about 430 ppm CO
2
e, this
carbon that cycles through atmosphere, living organisms,
implies limiting future increases to between 15 and 60 ppm
oceans and soil, we express quantities in terms of carbon
(Cowie et al. 2007; Eliasch 2008).
throughout this report. One tonne of carbon is equivalent
to 3.67 tonnes of carbon dioxide. The global carbon cycle
CARBON IN LIVING SYSTEMS
(see next page) illustrates how carbon moves and is stored
Living systems play a vital role in the carbon cycle. Photosyn-
in terrestrial and marine ecosystems and the atmosphere.
thesising organisms – mostly plants on land and various kinds
of algae and bacteria in the sea – use either atmospheric car-
CO
2
equivalent (CO
2
e) is a measure of global warming po-
bon dioxide or that dissolved in sea water as the basis for the
tential that allows all greenhouse gases to be compared
complex organic carbon compounds that are essential for life.
with a common standard: that of carbon dioxide. For exam-
The vast majority of organisms, including photosynthesising
ple, methane is about 25 times more potent a greenhouse
ones, produce carbon dioxide during respiration (the breaking
gas than carbon dioxide so one tonne of methane can be
down of organic carbon compounds to release energy used by
expressed as 25 tonnes CO
2
e.
living cells). Burning of carbon compounds also releases car-
bon dioxide. Methane is produced by some kinds of microbe as

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