Soil carbon sequestration under Miscanthus x giganteus - Jesko Zimmermann
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Soil carbon sequestration under Miscanthus x giganteus - Jesko Zimmermann
- 1. Soil carbon sequestration under Miscanthus x giganteus A large scale survey Jesko Zimmermann Jens Dauber Michael B. Jones
- 2. Miscanthus Miscanthus x giganteus • Ligno-cellulosic or „second generation“ bioenergy crop • Rhizomatous perennial grass with a C4 photosynthesis pathway • Originates in Asia (tropics and subtropics) • Remarkable adaptability to cool temperate climates • Introduction subsidised in Ireland Soil carbon sequestration potential due to physiological features and management practices Picture: Jens Dauber
- 3. Research questions Research on carbon sequestration mainly on experimental fields, however differences can be expected in commercial plots This study is focused on commercial large-scale Miscanthus fields in south east Ireland, looking at: • Soil carbon sequestration • Initial soil carbon loss • What is influencing the processes? Picture: Susannah Cass
- 5. Materials & Methods Sampling Nested sampling design A number of soil cores taken at three subplots in a Miscanthus field and an adjacent control site representing the former land-use Cores divided into three depth and bulked over the sub plot. Additional cores taken for bulk density
- 6. Materials & Methods Analyses The bulked samples were processed in the lab and following measurements were taken: Total organic carbon 13C/12C stable isotope ratio to determine the Miscanthus-derived carbon (13C natural abundance method) Soil bulk density, particle size distribution, and pH
- 7. SOC [Mg ha-1] SOC [Mg ha-1] -10.00 0.00 10.00 20.00 30.00 40.00 -10.00 0.00 10.00 20.00 30.00 40.00 Control Control 10 10 Miscanthus Miscanthus Control Control Depth [cm] Depth [cm] 20 20 Miscanthus Miscanthus Control Control C3-derived carbon C4-derived carbon 30 30 Miscanthus Miscanthus Tillage Grassland After Zimmermann et al., (2012) Global Change Biology Bioenergy, Vol. 4, Issue 4.
- 8. Field-scale study Picture: Susannah Cass
- 11. MG14 TCD_2_1 Average patch area 4.357 m2 3.710 m2 Standard deviation 8.702 25.245 No. Patches 901 1243 Sum of patch area 0.393 ha 0.461 ha Overall field size 4.390 ha 3.982 ha Share of field 8.95 % 11.58 % Zimmermann et al. (in prep.)
- 12. Farm Area [m2] SD Radius [m] SD MT3 8.672 6.287 1.519 0.691 MT5 8.151 4.111 1.570 0.372 MT6 10.595 6.028 1.772 0.496 MG11 18.185 14.109 2.233 0.923 MG18 4.329 1.965 1.146 0.264 MG20 10.488 6.335 1.751 0.537
- 14. MG11 MG18 MG20 Farm MT3 High MT5 Medium MT6 Low -50 -40 -30 -20 -10 0 Difference to area of a non-patch field [%] Zimmermann et al. (in prep.)
- 15. Miscanthus-derived carbon [Mg ha-1] -0.50 0.50 1.50 2.50 -0.50 0.50 1.50 2.50 10 10 20 20 High density 30 Open patch 30 Tillage Grassland Zimmermann et al. (in prep.)
- 16. Farm scale
- 18. High MT6_2 Mean MT6_1 Low MT5 MT3 MG20 MG18 MG11 -40 -30 -20 -10 0 Difference in Miscanthus-derived carbon to a no-patch field [%]
- 19. Conclusions Measurable soil carbon sequestration even 2 to 3 years after planting Miscanthus No significant loss of soil organic carbon due to plantation High variability between farms Crop patchiness has significant impact on yield and soil carbon sequestration
- 20. Acknowledgements David Bourke Susannah Cass Kees-Jan van Groenigen Kate Harte Bas Boots The Simbiosys Team Katie Wennig Catherine Fontana The land-owners for their Zeno Wong kind permission to work on Maximilian von Sternburg their lands Erin Jo Tiedeken Sarah Kimberley The EPA for funding the project