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Paludiculture on marginal lands – sustainable use of wet peatlands
Claudia Oehmke, Tobias Dahms, Sabine Wichmann & Wendelin Wichtmann
Worldwide, undrained peatlands (>3 million km²) presently sequester up to 100 Megaton of carbon per year
Denmark
Peatlands in the world…
peatland degradation on 65 million ha - a source of app. 5% of the total anthropogenic CO2
Dry arable land cultivation is worldwide applied to wet,
organic soils…
Greta Gaudig Germany
… with African desert plants on drained peat: Aloe vera…
Bostang Radjagukguk Kalimantan
Germany
… or semi-arid Maize on drained peat…
… or with oil palm on drained peat…
Malaysia
…peatland use that often does not even allow harvest…
Jilin, China
… a land use that has desertified millions of hectares…
Ukraine
…and in continental areas creates soils like made of stone…
Ukraine
Peatland drainage causes even greater problems: subsidence!
1939
2013
UK: 4 meters since 1870
Peatland management and GHG emissions
Couwenberg et al. (unpubl.)
-40
-20
0
20
40
60
80
100
-150 -100 -50 0 50
× 1
00
0 k
g C
O2e
/ha*
yr
Mean annual water table (cm)
-40
-20
0
20
40
60
80
100
-150 -100 -50 0 50
× 1
00
0 k
g C
O2e
/ha*
yr
Mean annual water table (cm)
Drainage based
peatland utilization
Low intensity
utilization of peatlands
Paludiculture
Peatland management and GHG emissions
Couwenberg et al. (unpubl.)
Rewetting reduces the emissions very effectively
Rewetted polders in the Peene river valley, Germany
Paludiculture
• Cultivation of biomass on wet and rewetted peatlands
bogs – sphagnum farming
fens - Common Reed, Reed Canary Grass, Sedges, Alder, Cattail...
• Utilisation of biomass for industry and energy
*„palus“ – lat.: swamp
Sphagnum farming for growing substrates
photos: University of Greifswald
Sphagnum: test field in Hankhausen (D) Productivity: 3 – 8 t (d.b.)/ha*a Emissions: up to 5 t CO2 – Äqu. / ha*a
Cattail as insulation
Common Reed for Roof Thatch
Mobile Pellet Mill
Biomass Pellets
Mobile Pelletpresse
Common Reed 10,5 t
Sedges 9 t + Reed Canary Grass 3 t
total 22,5 t
Biomass Pellets
Biomass harvest in summer
Hey for Combustion
Area potential
Hey for Combustion
Sustainable heat generation
Hey for Combustion
• current agricultural legislation:
the receipt of direct payments (CAP, First Pillar) and funding for rural development (CAP, Second Pillar) is common practice for drained petlands but seems impossible for reed and cattail dominated paludicultures (winter harvest).
• the establishment of permanent paludicultures on permanent grassland can be hampered by the rules protecting permanent grassland
The main hindering factors for large scale rewetting and paludiculture
– introduce at least an equal treatment of paludiculture compared to drainage based peatland agriculture regarding CAP payments,
– generally allow conversion from EU protected permanent grassland on organic soils to reed or cattail dominated paludiculture.
To make it happen:
`peatland rich’ countries must request constructive solutions for paludiculture on EU level
EU should arrange regulations that it is possible to
RRR 2017 conference http://www.paludiculture.uni-greifswald.de/en/projekte/rrr2017/
1 ha Common Reed = 3000 l Heat oil
Vielen Dank!
Reed production Preparation of transport and unloading at the peatland site
Planting of reed by machine
After 2 years
Mobile Pelletpresse
Common Reed 10,5 t
Sedges 9 t + Reed Canary Grass 3 t
total 22,5 t
Biomass pellets
DIN EN 17225-6
Common Reed Sedges
Reed Canary Grass Pine pellets
ash content % ≤5 2.1 5.0 2.8 0.5
mechanical durability
% ≥97.5 93.5 99.1 91.7 97.5
net calorific value MJ/kg ≥14.1 17.8 17.9 18.4 18.7
bulk density kg/m³ ≥600
630 670 634 634
N % ≤1.5 0.5 1.0 1.0 0.3
Cl % ≤0.2 0.02 0.3 0.1 0.001
S % ≤0.2 0.1 0.1 0.1 0.01
• Common Reed
• Cattail
Material utilisation Energetic utilisation
Paludiculture on fens
• Common Reed
• Sedges
• RCG
Summer im Winter Winter
• Common Reed
• Sedges
• RCG
Building material Biogas Combustion
Cost calculation bundles for thatching
• yield: 500 bundles /ha
• revenues: 2.00 € /bundle
Deterministic Calculation Point values
Revenues from the sale of biomass € ha-1 1000
variable machinery costs € ha-1 - 112
labour costs € ha-1 - 280
Contribution margin I € ha-1 608
fixed machinery costs € ha-1 - 125
Contribution margin II € ha-1 483
300 – 1000 bundles 1.90 – 2.50 € (3.50 €)
Stochastic simulation ranges
Contribution margin II € ha-1 -162 – 1542
S. Wichmann
(Wichmann 2016)
0%
25%
50%
75%
100%
0,000
0,001
0,002
0,003
0,004
-1.250 -1.000 -750 -500 -250 0 250 500 750 1.000 1.250 1.500
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Contribution margin II [€ ha-1 a-1]
<1%
(Wichmann 2016) Comparing profitability
Stochastic simulation: ranges, distribution, 10,000 iterations
(Wichmann 2016) Comparing profitability
Stochastic simulation: ranges, distribution, 10,000 iterations
<1%
Contribution margin II [€ ha-1 a-1]
+ 300 €
+ 200 €
Increase economic viability and competiveness of plaudiculture
Comparing profitability
Stochastic simulation: ranges, distribution, 10,000 iterations
(Wichmann 2016)
Direct payments + additional incentives
<1% 0%
Contribution margin II [€ ha-1 a-1]
Example: common reed
• Rewetting results in a GHG emission reduction of 15 t CO2-eq∙ha-1∙a-1.
• The reed of 1 hectare can replace fossil fuels in a cogeneration plant that would otherwise emit 15 t CO2.
• Emissions from handling amount to 2 t CO2-eq ha-1.
• Using reed from paludiculture would thus avoid emissions of almost 30 t CO2-eq∙ha-1∙a-1
Peatmosses (Sphagnum palustre, S. papillosum)
Yield: 3 – 8 t DM a-1 ha-1
growing media
Worldwide inventory of potential paludiculture plants..
Kalimantan
Rewetting with paludiculture reduces peatland emissions and produces renewable biomass resources: Jelutung rubber tree
Indonesia
Open questions on paludiculture
Basic literature on restoration
• Bonn, A., Allott, T, Evans, M., Joosten, H. & Stoneman (eds.) 2016. Peatland restoration and ecosystem services - Science, policy and practice. Cambridge University Press, Cambridge. Available on HIS.
• Brooks , S. , Stoneman , R. , Hanlon , A. & Thom , T. 2014. Conserving bogs: The management handbook . 2nd edn. York : Yorkshire Peat Partnership . Available on HIS.
• Grootjans, A.P., van Diggelen, R., Joosten, H. & Smolders, A.J.P. 2012. Restoration of mires. In: Van Andel, J. & Aronson, J (eds.): Restoration ecology: the new frontier. 2nd edition. Blackwell Publishing, Oxford, pp. 203-213. Available on HIS.
Literature
• Kozulin, A. V., Tanovitskaya, N. I. & Vershitskaya, I. N. 2010. Methodical recommendations for ecological rehabilitation of damaged mires. Available on HIS
• Schumann, M. & Joosten, H. 2008. Global peatland restoration manual. Available on HIS
• Timmermann, T., Joosten, H. & Succow, M. 2009. Restaurierung von Mooren. In: Zerbe, S. & Wiegleb, G. (eds.): Renaturierung von Ökosystemen in Mitteleuropa. Spektrum, Heidelberg, pp. 55-93. Available on HIS.
Thanks a lot for listening
The Greifswald Mire Centre Global Knowledge Hub for Peatlands
Greifswald University, Michael Succow Foundation, Duene e.V.
Where I come from
Greifswald, Federal State Mecklenburg Western Pomerania, Germany
Partners in the Greifswald Mire Centre (GMC)
• Ernst-Moritz-Arndt-University Greifswald Research
• Michael Succow Foundation Implementation, Nature protection
• DUENE e.V. Consultancy, Implemementation
Interface between Science and Politics refering to mires and peatlands
• Integrative roof for peatland related activities in Greifswald • about 50 scientists working on different peatland related issues • Main topics: Climate protection: Reduction of GHG emissions from peatlands
Biodiversity: Protection and restoration of peatlands
Sustainable Use: Paludiculture and innovative instruments and incentives fo peatland management
science-based solutions for social challenges, for all peatland related questions – locally and globally
The GMC
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