Whilst researching the carbon sequestration potential of peatlands for my dissertation, I came across the concept of "peatland geoengineering". The concept of peatland geoengineering is a
recent and niche addition to the growing field of geoengineering. I have to admit I was intrigued: I would never have associated peatlands with geoengineering.
Peatlands are extensive
accumulations of slow-decaying organic matter formed under waterlogged conditions in the
absence of oxygen. They are primarily distributed in the northern hemisphere:
Europe, North America and circumpolar regions, as well as in tropical South
East Asia (Figure 1) (Cris et al, 2014).
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| Figure 1: Global distribution of peatlands (Source: IUCN) |
Although they only constitute 3%
of the Earth’s surface – approximately 400 million ha – they store 1/3 of the
global soil carbon pool (Kochy et al, 2015). Peatlands have a higher carbon storage density per
unit than any other ecosystem in the world. In total, global peatlands are
estimated to store 450-600 gigatonnes of carbon (Yu et al, 2011).
Thus, the
carbon storage potential of peatlands is powerful. This is due to the primary
productivity exceeding the slow decomposition rate of plant litter. Due to
anaerobic decay suppressing decomposition, partially decaying plant remains
store carbon as peat (Zhang et al, 2016). The below video explores this in greater detail.
Keystone peatland species
Sphagnum is a genus of
peat moss – characterised by its spongy texture and large water absorption
potential. They are principal peat-forming species due to their role in
ecosystem functioning; by strongly influencing the cycling of carbon, water and
nutrients. This contributes to an acidified, anoxic and
waterlogged state (Kotska, 2016).
Due to their large carbon sequestration potential, Sphagnum can dominate primary productivity in northern peatlands. Approximately 50% of northern peat volume is made up of decaying Sphagnum (Turetsky, 2003); thus making it one of the most efficient plants for carbon storage and peat formation (Gunnarsson, 2013).
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| Figure 2: Sphagnum moss in a peat-bog in Yorkshire, England (Source: Me) |
Due to their large carbon sequestration potential, Sphagnum can dominate primary productivity in northern peatlands. Approximately 50% of northern peat volume is made up of decaying Sphagnum (Turetsky, 2003); thus making it one of the most efficient plants for carbon storage and peat formation (Gunnarsson, 2013).
Manipulation of carbon storage potential
The following are proposed manipulation techniques to optimise carbon
storage potential (Freeman et al, 2012):
1) Installing dams
to increase waterlogging and reduce oxygen availability
2) Acid
fertilisaiton, e.g. ammonium sulphate, to increase competitive advantage of
keystone species such as Sphagnum by aiding productivity
3) Genetic modification
of Sphagnum to enhance phenolic production, which would further slow
decomposition.
4) Inserting
forestry waste into peatland to prevent timber decomposition which would
re-release CO2 into atmosphere.
Potential risks
In a warming climate, the potential for drought occurrence is much
greater (IPCC, 2007). This is
particularly worrying for peatlands as drought stimulates aerobic
decomposition. This would result in large carbon loss, we are talking in terms
of gigatonnes, from peatlands and contribute to current CO2
emissions (Fenner and Freeman, 2011). Peatlands could therefore become a large positive feedback mechanism for global warming (Cris et al, 2014). Furthermore, a decrease in water table can release large amounts of
CH4: a much more potent greenhouse gas than CO2
Whilst ammonium sulphate fertilisers may increase peatland carbon
sequestration potential, excess fertiliser runoff into river catchments can
prove detrimental for the aquatic ecosystem (Higashino and Stefan, 2014). An excess of nutrients can cause
toxic algal blooms and decrease water quality (Chislock et al, 2013). This is particularly troublesome
in the UK as many large cities rely on upland peat-catchments for clean drinking water.
Unfortunately, I feel that advocators of nitrogen fertilisation as a
means to capture CO2 are missing a crucial point. As nitrogen is a limiting nutrient in peatland
ecosystems, there is a potential for ‘nitrophilous’ (nitrogen-loving) species
to capitalise on high influxes (Stevens et al, 2016). This is a well documented phenomenon in European
peatlands; which have exhibited a decrease in biodiversity and species richness
(Bobbink et al, 2010). Declines in the key stone Sphagnum
species, associated with nitrogen deposition, can significantly undermine the
formation, and thus carbon sequestration, of peat (Sheppard et al, 2014).
In conclusion, I think it is too early to rule out peatland
geoengineering, as there is still so much we don’t know about peatland
ecosystem functioning. At this stage in time, I am not too convinced and feel
more research needs to be dedicated to this field.
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