1. Challenges and options John Couwenberg Hans Joosten Greifswald University Are emission reductions from peatlands MRV-able

2. Stocks & emissions Current Carbon stock in peat soils: ~550 000 Mt C Current emissions from drained peatlands: >2000 Mt CO 2 y -1

3. Global CO 2 emissions from drained peatlands Drained area (10 6 ha) CO 2 (ton ha -1 y -1 ) Total CO 2 (Mton y -1 ) Drained peatlands in SE Asia1250600 Peatland fires in SE Asia400 Peatland agriculture outside SE Asia3025750 Urbanisation, infrastructure530150 Peat extraction30160 Boreal peatland forestry121 Temperate/tropical peatland forestry3.530105 Total632077

4. Mitigation management options Conservation of the C stock Sequestration of C from the atmosphere Substitution of fossil materials by biomass.

5. Conservation management Conserve existing peat C pools: Prevent drainage Reverse drainage by rewetting

6. yearly emissions time Reducing the rate of deforestation (rate of reclamation of new areas)

7. yearly emissions time Reducing the rate of peatland drainage (rate of reclamation of new areas) Peatlands continue emiting for decades after drainage: Annual emissions are cumulative

8. Conservation management Rewetting is the only option to reduce emissions Strategic rewetting of 30% (20 Mio ha) of the world’s drained peatlands could lead to an annual emission avoidance of almost 1000 Mtons CO 2 per year.

9. Sequestration management ~75% of peatlands are still pristine accumulating new peat removing & sequestering 200 Mtons CO 2 y -1  strict protection rewet 20 Mio ha restore peat accumulation in 10 Mio ha  additional removal ~10 Mtons CO 2 y -1

10. Substitution management replacing fossil resources by biomass from drained peatlands:  CO 2 emitted > CO 2 avoided biomass from wet peatlands or paludiculture (= wet agriculture and forestry) implemented on 10 Mio ha of rewetted peatland  substitution of 100 Mtons of CO 2

11. Peatland management avoiding peatland degradation and actively restoring peatlands results in significant climate benefits  quantify emission reductions

12. Measure drained…

13. … and (re-)wet(ted) situation...

14. frequent, prolonged, intensive

15. expensive, complex, time consuming

16. Peenetal Measure pilot sites, develop proxies for the rest

17. Proxies: water level -120-100-80-60-40-200 mean annual water level [cm] t CO2 ha -1 y -1 0 10 20 30 40 50 Good proxy for CO 2 emissions: Example temperate Europe

18. Proxies: water level -100 0 100 200 300 400 500 600 -100-80-60-40-200204060 mean water level [cm] kg CH 4 ?ha y -2 0 2 4 6 8 10 12 t CO 2 -eq?ha y Good proxy for CH 4 emissions: Example temperate Europe

19. Proxies: water level Good proxy for CH 4 emissions: Boreal/temp Europe SEAsia At high water levels differences due to vegetation

20. Emissions strongly related to water level Vegetation strongly related to water level  Use vegetation as indicator for emissions

21. Proxies: vegetation developed for NE Germany currently being verified, calibrated and updated for major peatland rewetting projects in Belarus.

22. Proxies: vegetation Advantages of using vegetation reflects longer-term water level conditions reflects factors that determine GHG emissions (nutrient availability, acidity, land use…), itself determines GHG emissions (quality of OM, aerenchyma mediated CH 4 ) allows fine-scaled mapping (1:2,500 – 1:10,000)

23. Proxies: vegetation Disadvantage of using vegetation slow reaction on environmental changes necessity to calibrate for different climatic and phytogeographical conditions.

24. GESTs: Greenhouse gas Emission Site Types

25. GESTs with indicator species groups GEST: moderately moist forbs & meadows Vegetation forms: Urtica-Phragmites reeds Acidophilous Molinia meadow Dianthus superbus-Molinia meadow … Each with typical / differentiating species Each GEST with GWP

26. Proxies: subsidence loss of peatland height due to oxidation complication: consolidation, shrinkage promising especially in the tropics: subsidence based methodology being developed by the Australian-Indonesia Kalimantan Forests Carbon Partnership.

27. Proxies: subsidence Oxidative component derived from changes in bulk density and ash content:

28. Proxies: subsidence possible to measure using remote sensing and ground-truthing works well for losses from drained peatlands, but less for decrease in losses under rewetting (swelling)

29. Monitoring emission reductions from rewetting and conservation wide range of land use categories may require different approaches to –reduction of GHG emissions –monitoring these reductions land use may enhance GHG emissions (plowing, fertilization, tree removal)

30. Monitoring emission reductions from rewetting and conservation Avoided emissions need clear baseline clear in case of rewetting proxy approach for avoided drainage –Note: peat depth determines duration of possible emissions after drainage

31. Monitoring emission reductions from rewetting and conservation cost of monitoring is related to the desired precision of the GHG flux estimates. determined by market value of ‘carbon’ assessing the GHG effect of peatland rewetting by comprehensive, direct flux measurements might currently cost in the order of magnitude of € 10 000 ha -1 y -1

32. Monitoring by proxies Monitoring GHG fluxes using water levels: data frequent in time, dense in space.  field observations and automatic loggers. water level modelling based on weather data remote sensing not yet suited

33. Monitoring by proxies Monitoring GHG fluxes using Vegetation: easily mapped and monitored in the field monitoring by remote sensing has been tested successfully and is very promising, also in financial terms.

34. Monitoring by proxies Monitoring GHG fluxes using subsidence: easily monitored by field observations, but practically impossible over large areas when annual losses are high. In tropical peatlands (several cm y -1 ) the use of LiDAR looks very promising.

35. Monitoring of proxies derivation of actual emissions from proxies open to improvement

36. conservative estimates indicate that reduced and avoided emissions from peatland rewetting and conservation can provide a major contribution to climate change mitigation