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Effects of Land Use Change on Soil Organic Carbon Dynamics in Northwestern Vietnam

SFB 564 The Uplands Program. Effects of Land Use Change on Soil Organic Carbon Dynamics in Northwestern Vietnam Volker Häring 1 , Holger Fischer 2 , Georg Cadisch 3 , Karl Stahr 2 1 Dpt. o f soil science and soil ecology, University of Bochum, Germany

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Effects of Land Use Change on Soil Organic Carbon Dynamics in Northwestern Vietnam

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  1. SFB 564 The UplandsProgram Effects of Land Use Change on Soil Organic Carbon Dynamics in Northwestern Vietnam Volker Häring1, Holger Fischer2, Georg Cadisch3, Karl Stahr2 1Dpt. of soil science and soil ecology, University of Bochum, Germany 2Institute of soil science and land evaluation, University of Hohenheim, Germany 3Institute of plant production in the tropics and subtropics, University of Hohenheim, Germany EGU 2014

  2. Introduction Understanding of SOC dynamicsis relevant for: Climatechange Soilfertility • SOC changesaffect e.g. • Cationexchangecapacity • Aggregate stability • Field capacity SoilsAthmosphere Vegetation 1500 Pg 730 Pg 500 Pg C (IPCC et al., 2000) Land usechangefromforesttocropleadto a netdeclineof 20-40% ofinitial SOC (Murty et al., 2002) • Soilsare a large but labile C sink!

  3. Research sites Hanoi Yen Chau Vietnam Cutanic Alisol (Chromic) on limestone Cutanic Luvisolon clayeyshale Vertisolon marl Research sitesin Yen Chau district

  4. Aims & Methods 1. Determination ofnet SOC input, SOC decomposition, SOC erosion Chronosequences Corg, δ13C, bulkdensity 137Cs Sampling 0-30 cm depth CIDE approach 2. Determination oftheeffectsoftillage on SOC dynamics Tillage vs. naturaldecomp.

  5. CIDE (Carbon Input, Decompositionand Erosion) • CIDE overcomes traditional δ13C basedmassbalanceapproachesandmorereliablydeterminesC dynamics on erosionproneslopes • CIDE considerspastsoilerosion • Otherwisecarbonbudgetingunderestimates C loss • 2. CIDE considerserosioninducedsoilprofiletruncation: • Otherwiselower C contentandhigherδ13C aremeasuredalthoughno • cultivationtookplace Soilsurface (t1) Sampling depthwithmeanvalue t1 Decomposition C Input Erosion t0 t0 t1 Häring et al. (2013a) EJSS 65 (5)

  6. SOC after landusechange Apparentnet SOC change(depthofeachsitebulkdensitycorrected) Luvisol Vertisol Alisol Means ±SE; n=5 • Exponentialnet SOC declinewith time on all soiltypes Häring et al. (2013b) SBB 65, 158-167

  7. SOC after landusechange Apparentforestandmaizederived SOC change(based on total C, bulkdensityandδ13C) Luvisol Vertisol Alisol Maize SOC Forest SOC Means ±SE; n=5 • Maize SOC inputincreasedlinearlywith time • Input islow: After 15 yearsitis still oneorderofmagnitudesmallerthanforest SOC Häring et al. (2013b) SBB 65, 158-167

  8. SOC loss after landusechange CIDE derived total SOC lossand CIDE decomposition vs. unadjusted SOC loss Luvisol Vertisol Alisol R²=0.92 R²=0.65 R²=0.88 R²=0.69 R²=0.62 R²=0.32 R²=0.81 R²=0.84 R²=0.79 Means ±SE; n=5 • CIDE total SOC lossishigherthanapparent SOC loss(at 15 years) by • 6% on Alisol • 28% on Luvisol • 32% on Vertisol Häring et al. (2013b) SBB 65, 158-167

  9. SOC input after landusechange CIDE vs. apparent SOC input Luvisol Vertisol Alisol R²=0.88 R²=0.78 R²=0.15 R²=0.16 R²=0.81 R²=0.46 Means ±SE; n=5 • CIDE SOC inputislowerthanapparent SOC input(at 15 years) by • 14% on Alisol • 21% on Luvisol • 41% on Vertisol Häring et al. (2013b) SBB 65, 158-167

  10. Tillage vs. naturaldecomposition Evidencefortillagedecomp. bychangeofforestderived SOC withdepthand time Luvisol Vertisol Alisol R²=0.31 R²=0.03 R²=0.04 R²=0.04 R²=0.31 R²=0.10 Means ±SE; n=5 Häring et al. (2013b) SBB 65, 158-167 • Declineof linear fitsofratiosover time indicatethat in onelayer relative decompositionishigherthan in theother • Declinebetween 0-10 & 10-20 cm but nosignificantdeclinebetween 10-20 & 20-30 cm • Nosignificantdecline in Vertisolsat all depths • Tillageaccelerateddecomposition in theploughlayer (0-10 cm) on Luvisol and Alisol

  11. Tillageinduceddecomposition Tillagedecomposition rate calculatedasoffsetbetweendeclineat 0-10 cm and parallel distributionofratiowith time Alisol f(t) = 0.05t R² = 0.15 Luvisol f(t) = 0.04t R² = 0.40 Vertisol f(t) = 0.001t R² = 0.002 Means ±SE; n=5 • Tillagedecompositionaccountedfor 3 to 34% of total decomposition Häring et al. (2013b) SBB 65, 158-167

  12. Conclusions • A newapproach (CIDE) todetermine SOC dynamics on erosionproneslopes was presented • SOC loss on erosion prone sites is underestimated and SOC input overestimated with traditional approaches • Distribution of forest derived SOC with depth and time revealed tillage induced decomposition • Tillage increased decomposition (3-34% of total decomposition) in the plough layer • References: • Häring V. et al. (2013a): Improved 13C method to assess soil organic carbon dynamics on sites affected by soil erosion. EJSS 65 (5), 639‐650. • Häring V. et al.(2013b): Implication of erosion on the assessment of decomposition and humificationof soil organic carbon after land use change in tropical agricultural systems. SBB 65, 158-167

  13. SFB 564 Thankyouforyourattention! Acknowledgements …theDFGforfunding, …Thuy Nguyen HuuandNguyen Thuy Ha forfieldassistance, …M.Sc. studentsChristianSchehleandJulia Auber …Bachelor studentSteffen Schweizer …Trainees Nadja Reinhardt and Laura Kiff …ourLab-Teamin Hohenheim …andallcontributingfarmers in Vietnam

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