1 / 18

Sustainable Agroforestry in Degraded Drylands: Win – Win Approaches for Local, Regional and Global Problems

Sustainable Agroforestry in Degraded Drylands: Win – Win Approaches for Local, Regional and Global Problems. Leu S. and Mor-Mussery A. in collaboration with the Sustainability Laboratory . Overexploitation  Land Degradation by. - Productivity. Mismanagement. - Biodiversity.

elu
Download Presentation

Sustainable Agroforestry in Degraded Drylands: Win – Win Approaches for Local, Regional and Global Problems

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. Sustainable Agroforestry in Degraded Drylands: Win – WinApproaches for Local, Regional and Global Problems Leu S. and Mor-Mussery A. in collaboration with the Sustainability Laboratory

  2. Overexploitation Land Degradation by -Productivity Mismanagement -Biodiversity -Resilience and Sustainability -Carbon Stocks Acceleration of and Sensitization to Effects of Global Warming

  3. 2. Rehabilitation by Restoration of Vegetation Productivity + Management Biodiversity + Resilience and Sustainability + Carbon Stocks + Mitigation of and Adaptation to Effects of Global Warming!

  4. N Topography Analysis and Engineering Requirements Engineering or Forestry

  5. Site plan Fenced Green Tree To border between the different fields and supplement extra use (crop, pasture, shade etc…) Shade trees The shade pathways Silvipasture Savanna trees with additional uses (mainly pasture), suited to arid zones, Riverine, native plants *Plants the will be suited in the edges of the river

  6. The area excluded by the black line is unsuitable for large agricultural plots, while areas 1 – 4 do not pose any problems except for small corrections along the river; • The following pictures demonstrate these facts;

  7. Large Rocky Slope with Wadis Unstable Wadi and Soil 200m Stable Wadi Only the two marked rhomboids are suitable for agriculture, about 10 and 5 dunam;

  8. The Soil in the southern-most Wadi is highly erosive; these erosion structures have to be stabilized by terraces, planting of mixed trees, olive plantations and high value trees; Native trees will be incorporated for high grazing value, biodiversity and agricultural return;

  9. Technique1: Restoration of vegetation, erosion control and tree planting using contour drip irrigation Trees and Shrubs were planted along drip irrigation, every 2m one line was established, and every dripper received 100L of water during November-December 2008.

  10. Technique2: Restoration of land using dryland trees The number of functions fulfilled by dryland trees is huge • Carbon Sequestration into biomass; • Recovery of nutrients from deep soil; • Enrichment and protection of top soils by plant litter; • Increasing productivity of annual vegetation; • Preventing wind erosion; • Providing shade to animals and buildings; • Preventing water runoff and erosion; • Restoring natural habitats and biodiversity; • Providing fodder during the dry season; • Providing biomass energy; • Providing high value oils and fruit for economic expansion;

  11. Fact: Woodland trees Sequestrate high Carbon amounts into biomass 20 years old Acacia victoriawoodland near Yattir farm (220 mm mean Annual Precipitation) 2.5 t per ha and year annual vegetation; 2.5 tons per ha and year tree litter (edible); 1 ton per ha and year woody biomass; 6 tons per year CO2 sequestration; Supports 2 goats per ha: RICH ANIMAL LIFE Degraded land nearby: 0.5 t per ha and year annual vegetation NO tree litter! NO woody biomass! NO CO2 sequestration! Supports 0.2 goats per ha NEGLIGIBLE ANIMAL LIFE!!! *Problem: Acacia victoria is not a native species!

  12. Facts: Grazing Improvement, Land Rehabilitation and Biomass Production by Silvipasture Biomass and Litter under Tree Canopy and in nearby Open Areas: Suitable Trees Promote Growth of Annual Vegetation and Provide Extraordinary Amounts of Organic Litter!

  13. Left: niche of wheat growing without need of irrigation and nutrient supply; Right: Small olive tree survives inside the Acacia victoria woodland, taking advantage of higher soil fertility and humidity, reduced evaporation and protection from wind by the other trees. Facts: Using trees for agriculture purposes in arid environments

  14. planting techniques: The planting method dramatically affects soil characteristics Contour Trenching Planting without Soil Disturbance

  15. Terrace Agroforestry using Natural Topography A simple stone terrace suffices to create excellent conditions for Olive cultivation. The reduced water runoff intensity allows natural vegetation to recover as well.

  16. Other Crops Used for Intercropping: • Vegetables • Watermelons • Sunflowers • Tobacco Classical agroforestry with summer sorghum (left behind) intercropped with olive trees. The humidity stored in the soil of the dammed areas suffices to maintain growth of sorghum throughout the hot, completely dry summer. Intercropping in Agroforestry Terraces

  17. Principle of Soil Management: THE MOST IMPORTANT: Exposed Soil Degradation An area covered by manure (right) displayed very significant plant growth in spite of very poor rainfall (~110 mm in 2009), in contrast to the exposed soil to the left.

  18. Expected Benefits at Wadi Attir • Carbon sequestration compensating for the agricultural greenhouse gas emissions. • Water savings by optimized agricultural production, wind breaks, plant litter and no till agriculture; • Reduced fertilizer use due to nitrogen fixing plants and nutrient recovery from deep soil by trees; • Improved biodiversity due to planted native trees; • Increased profitability due to growing amounts of high quality high price oils; • Providing waste biomass for energy production from tree trimming; • Reduced erosion and soil loss due to terrace agroforestry and erosion barriers;

More Related