Benefits of Installing Shelterbelts April 2006

1. Benefits of Installing ShelterbeltsApril 2006 André Vézina, ITA, La Pocatière Campus

2. Reasons for planting shelterbelts around livestock buildings • Odour mitigation • Reduction of heating costs • Control of snow accumulation • Reduction of air-conditioning costs • Reduction of dust volume • Protection for livestock • Aesthetic enhancements to surroundings • Enhanced biodiversity • Secondary productions • Reduction of greenhouse gas emissions André Vézina, ITA, La Pocatière Campus

3. How shelterbelts help mitigate odours(Tyndall and Coletti, 2000) • Dilution of gas concentrations • Dust and aerosol deposition • Interception of dust and aerosols • Absorption of chemical constituents of odours André Vézina, ITA, La Pocatière Campus

4. Dilution of gas concentrations André Vézina, ITA, La Pocatière Campus

5. If temperatures are favourable, and if the site topography is flat and free of obstacles, air circulation close to the ground will cause objectionable odours to be less noticeable. André Vézina, ITA, La Pocatière Campus

6. Turbulent zone (plume dilution) Shelterbelt Quiet zone Distance from shelterbelt (H) (Adapted from Raine, 1974, as used in McNaughton, 1988) André Vézina, ITA, La Pocatière Campus

7. Artificial windbreaks used to deflect ventilated air upward, so that foul air flows higher above the ground, can noticeably reduce odours downwind (OCTF, 1998; Bottcher et al., 1999). André Vézina, ITA, La Pocatière Campus

8. Dust and aerosol deposition André Vézina, ITA, La Pocatière Campus

9. Air containing dust particles can carry a greater amount of odour-producing molecules than the same volume of dust-free air (OCTF, 1998). • In average, a windbreak with a porosity of 40% will reduce wind velocity by 50% over 10 H, and by 25% over 10-20 H (Vézina, 1985). • This reduction will cause wind-borne particles to be deposited. André Vézina, ITA, La Pocatière Campus

10. Wind tunnel modeling of a three-row shelterbelt system has quantified reductions of 35-56% in the downwind mass transport of odorous particles (dust and aerosols) (Laird, 1997; Thernelius,1997). • Other studies have shown a 70-90% reduction in pesticide concentrations on the lee side of shelterbelts made of hardwoods (Porskamp et al., 1994). André Vézina, ITA, La Pocatière Campus

11. Interception of dust and aerosols André Vézina, ITA, La Pocatière Campus

12. Absorption of chemical constituents of odours André Vézina, ITA, La Pocatière Campus

13. Significant quantities of volatile organic compounds have been measured on the surface of plants and within plant tissues(Reischl et al., 1989; Gaggi et al., 1985). Micro-organisms that dominate the surface of plants absorb volatile organic compounds, thus providing additional surface area for pollution collection. These organisms also have the ability to metabolize and breakdown volatile organic compounds (Screiber and Schonherr, 1992; Mueller, 1992). André Vézina, ITA, La Pocatière Campus

14. Choinière Project (2004): Evaluating the performance of mature shelterbelts in mitigating odours André Vézina, ITA, La Pocatière Campus

15. Reduction in length of odour plumes by 19%, 23% and 25% compared to control F factor (odor limits) Distance Source/wb Odor plume lengthLength reduction No windbreak André Vézina, ITA, La Pocatière Campus

16. Reduction in surface area of odour plumes by 30%, 33% and 37% compared to control Odor plume areaLength reduction Distance Source/wb No windbreak André Vézina, ITA, La Pocatière Campus

17. Average dilution ratio vs. distance between odour source and hedge Hardwoods Average (Hdw-Cnf) Conifers Odour dilution is enhanced by a ratio of 1.9, 3.2 and 5.1, respectively at distances of 60 m, 30 m and 15 m. André Vézina, ITA, La Pocatière Campus

18. Reduction in heating costs 10-15% in NE USA (Heisler and De Walle, 1988) 27% in Western Canada (PFRA) (1.2% per km/h in wind speed in unprotected areas) André Vézina, ITA, La Pocatière Campus

19. Shading created by trees and shrubs can lower temperatures by 10-14°C, thus reducing air-conditioning costs by 50-70% (Gaudet, 1985). The trees should be planted on the western side of the buildings to ensure optimal protection during the summer without significantly reducing solar radiation during the winter (USDA, 1985). André Vézina, ITA, La Pocatière Campus

20. Control of snow accumulation André Vézina, ITA, La Pocatière Campus

21. Improved weight gain and reduced death rate in livestock. André Vézina, ITA, La Pocatière Campus

22. Shading is beneficial to animals. For example, milk production starts to decline when temperatures exceed 20°C (Hintz, 1983). André Vézina, ITA, La Pocatière Campus

23. A dense hedge of trees and shrubs has been shown to reduce by one-third the volume of decibels generated by normal road traffic in a peri-urban area in Nebraska (Cook and Van Haverbeke, 1976). André Vézina, ITA, La Pocatière Campus

24. Shelterbelts have the ability to collect a portion of air-borne dust particles. According to Dochinger (1980), dust fall can be reduced by 38% with the use of coniferous shelterbelts and by 27% with hardwoods, compared to an area that contains no trees. André Vézina, ITA, La Pocatière Campus

25. Aesthetic enhancements to surroundings André Vézina, ITA, La Pocatière Campus

26. Presence of trees and shrubs is of considerable help in enhancing biodiversity (Boutin et al., 2003; Deschênes et al., 2003; Maisonneuve and Rioux, 2001). Their study included six types of buffer strips: grasslands, grass-like strips, low-growing scrublands, high-growing scrublands and wooded hedgerows. It is in these wooded hedgerows that the highest population and greatest diversity of birds was found as well as the highest populations of amphibians and reptiles. The total number of small mammals captured increases from grasslands to scrublands to wooded hedgerows. Enhanced Biodiversity André Vézina, ITA, La Pocatière Campus

27. Secondary productions • Wood • Berries • Nuts • Branches André Vézina, ITA, La Pocatière Campus

28. Hybrid poplars 110 clones Lapotika Farm, La Pocatière André Vézina, ITA, La Pocatière Campus

29. Planted en 1981, harvested in 2005 André Vézina, ITA, La Pocatière Campus

30. Yield • 1 m3/tree • 90% lumber • 7 trees/cord André Vézina, ITA, La Pocatière Campus

31. We expect better results from some selected clones André Vézina, ITA, La Pocatière Campus

32. Study conducted on 10 shrub species (La Pocatière, 2004-2006) André Vézina, ITA, La Pocatière Campus

33. Preliminary results (www.cepaf.ca) • Sambucus canadensis, aronia melanocarpa, viburnum trilobum and rosa rugosa gave the best yields among the shrubs under investigation. • Sambucus canadensis show the best yields (1,25 kg per plant), but we expect the plants to give more as they reach their full production potential. André Vézina, ITA, La Pocatière Campus

34. Branches • Trends in floral design have increased the demand for branches from a number of shrubs with decorative flowers and fruits, as well as branch form and color. A study is underway under the leadership of Bruno Moser, head of Purdue's Department of Horticulture, to develop a sustainable system to produce economic shoots of a number of plant species including the Salix caprea (pussy willow) and S. matsujdana tortuosa (corkscrew willow). André Vézina, ITA, La Pocatière Campus

35. Reduction of greenhouse gases (Rochette, 2000) Evolution of carbon emissions in Canada with and without Kyoto Protocol application André Vézina, ITA, La Pocatière Campus

36. This 3 row model is capable of sequestering 300 tons of carbon per kilometre of windbreak within a 40-year timeframe (PFRA (1997). By planting annually 100 km of hedgerows by 2010 in eastern Canada , it would be possible to mobilize, in 40 years, a total of 0,2Mt of CO2, which represents 0,03% of the forecasted annual production in Canada in 2010. A small step in the right direction… André Vézina, ITA, La Pocatière Campus

37. Inconveniences • Rodents (negligible) • Birds (negligible) • Higher odour concentrations in the area between the shelterbelt and the source of the odour • Increase (3°C) in air temperature within protected area André Vézina, ITA, La Pocatière Campus