1 / 28

Actions to Achieve Sustainable Agriculture while Responding to Climate Change Goals

Fahmuddin Agus Indonesian Soil Research Institute Jln . Juanda 98, Bogor 16123, Indonesia. Actions to Achieve Sustainable Agriculture while Responding to Climate Change Goals. REDD-plus after Cancun: Moving from Negotiation to Implementation Building REDD-plus Policy Capacity for

polly
Download Presentation

Actions to Achieve Sustainable Agriculture while Responding to Climate Change Goals

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Fahmuddin Agus Indonesian Soil Research Institute Jln. Juanda 98, Bogor 16123, Indonesia Actions to Achieve Sustainable Agriculture while Responding to Climate Change Goals REDD-plus after Cancun: Moving from Negotiation to Implementation Building REDD-plus Policy Capacity for Developing Country Negotiators and Land Managers 18-20 May 2011, Hanoi, Vietnam

  2. Coverage • Introduction • Indonesian agriculture • Actions to achieve sustainable agriculture and reduce emissions, and supporting policies needed • Conclusions

  3. Food crops Source: http://database.deptan.go.id/

  4. Production of major food crops (million ton) Source: http://database.deptan.go.id/

  5. Food crop agriculture • Area almost constant, intensification in rice and maize • Susceptible to extreme climate conditions (drought, flood) and indirect effects entailed (pest and diseases) • The main indicator for food security and affect social and political stability

  6. Development of plantation crops Source: http://database.deptan.go.id/

  7. Development of oil palm plantation High Yield (3.6 t PO/ha/yr) Low yld (1-2 t/ha/yr) Source: Dir. General of Estate crops (2010)

  8. PRODUCTION OF PALM OIL, 1967-2009 Source: Dir. General of Estate crops GE (2010)

  9. EXPORT OF PALM OIL Export volume Source: Central Bureau of Statistics (2010)

  10. Land use change to OP from 1990–2009 Source: Agus et al. 2011 (on-going study, unpublished)

  11. Plantation/tree based agriculture • Oil palm plantation area increases very rapidly. • Generate foreign exchange earning • Supports regional development , especially in Sumatera and Kalimantan islands • A driver of LUC • OP plantation provides employment to more than 3.5 millions households (as workers and farmers) or about 15 million people

  12. Agriculture in GHG Emissions Without LUCF Source: MoE, 2009 With LUCF

  13. Emission Rdxn target from the BAU of 2020 From REDD+ to REDD++ or REALU Source: MoE, 2009

  14. Actions that potentially reduce emission: Peatland • Avoided deforestation • Control of peat fire • Use of ameliorant • Water table control: as shallow as possible to the level that does not detriment plant growth • Prioritization of the use of drained peat shrubs for plantation development

  15. Actions on Mineral soil • Rehabilitation/utilization ofImperata grassland and shrublandfor tree-based farming • Soil organic matter management: minimum tillage, organic matter recycling, use of biochar

  16. 60 cm Processes entailed in peat forest conversion (1) Change in time average C stock 0~250 t C/ha 30-50 t C/ha (3) Peat (soil) burning Peat subsidence (peat) 300-800 t C/m/ha in peat soil 15-200 t C/ha in surface of mineral soil (2) Soil C oxidation

  17. Carbon balance related to LULUCF (t CO2/ha/year)

  18. Potential emission related to LUC on mineral soil Source: Agus et al. (2009)

  19. NAMA-LAMA and expected emission reduction in “Agriculture”

  20. Avoid deep drainage (reduce drainage depth by about 10 cm) in peatland agriculture

  21. Rehabilitation of shrubland with tree-based farming

  22. Rehabilitation of bare/Imperata grassland with tree based farming

  23. Soil organic matter management on (annual) upland agriculture

  24. Land swap for agric.extensificationfrom high C stock (including peat) land bank to low C stock areas within same district

  25. Summing the ER from Agric.(under very conservative assumptions)

  26. Basic Requirement for NAMA-LAMA Development • Emission factors • Verified and agreed land cover and land status map for developing LUC matrices

  27. Example of LUC matrix

  28. CONCLUSIONS • Indonesian agriculture intensifies and the area extends (esp. for OP) in response to domestic and international demands • Rehabilitation of low C-stock land to tree-based agriculture can reduce GHG emission and at the same time improve the economy and livelihoods. Clearance of land status and tenure is a prerequisite. • Technical and financial supports are required for developing smallholder tree-based farming. • Swapping the land bank to low C-stock areas promises a significant ER, but requires legal reform on land status. • Verified and agreed land cover and land status maps and emission factors are the key to moving forward

More Related