Urban Heat Island and Pollution

1. Urban Heat Island and Pollution

2. Summary • General circulation models: Grid size. Name of the basic set of equations. 4 components of the climate system model. • Mesoscale models: Grid size. • Global climate models can reproduce the observed warming in the 20th century. The warming is largely caused by human activities. • Projected change in mean: temperature (largest warming over NH continents), sea level, precipitation • Projected change in extreme: temperature, precipitation • Projected impacts: fresh water, ecosystems • Mitigation: We can make a difference by reducing waste of energy, food and other materials, and by purchasing environment-friendly products. Future climate scenarios show that reducing greenhouse gas emissions can substantially mitigate warming in the latter half of this century.

3. How do human activities change the global climate? • Release or cleanse greenhouse gases • Change land cover (urbanization, deforestation and afforestation) • Release or cleanse pollutants (aerosols)

4. Global urbanization map

5. Global urbanization prospects

6. The Heat Island Effect Temperature distribution for Atlanta (from EPA)

7. Effects of vegetation • Makes water/heat reservoir deeper (transport deep water • out of soil) • Enhances evaporation (leafs increase evaporation area) • Dependent on vegetation type

8. Vegetation feedbackVegetation in turn is affected by environmental conditions (e.g. seasons, droughts, global warming)

9. Effects of different surface types Convective instability increases Deeper heat reservoir (smaller T change) Deeper water reservoir (Wetter surface) Enhanced latent heat flux

10. The heat island effect • Nighttime: City warmer than surrounding rural area • Daytime: City has same air temperature as rural area

11. Temperature distribution for Atlanta (from EPA)

12. Dependence of heat island effect on population

13. Causes of the heat island effect “Canyons” between buildings • Increased SW absorption caused by canyon geometry (increased area and multiple reflection) • Decreased LW loss caused by canyon geometry • Increased greenhouse effect caused by air pollution • Anthropogenic heat source • Increased sensible heat storage caused by construction materials • Decreased latent heat flux caused by change of surface type • Decreased sensible and latent heat fluxes caused by canyon geometry (reduction of wind speed)

14. Mitigation of heat island effect • Greening the city (streets and roof top) • Change construction materials • Reduce anthropogenic heat sources

15. Air Pollution

16. Video: Science to Protect the Air We Breath (by EPA) • http://www.youtube.com/watch?v=3PO_3exwN-I

17. Introduction • Air pollutants are gases, liquids or solids in the air that can adversely affect plant and/or animal life. • Primary pollutants are pollutants that are emitted directly by natural or anthropogenic (manmade) processes. • Secondary pollutants are pollutants that arise from chemical reactions of atmospheric gases with gases emitted by natural or anthropogenic processes. • There are six major pollutants: particulates (PM2.5 (<2.5 µm)), carbon oxides, sulfur dioxides, nitrogen oxides, volatile organic compounds, ozone

18. Global distribution of PM2.5 (2001-2006) Image from NASA Credit: Dalhousie University, Aaron van Donkelaar

19. U.S distribution of PM2.5 (2001-2006) Image from NASA Credit: Dalhousie University, Aaron van Donkelaar

20. Atmospheric Conditions and Air Pollution (1) Effect of Winds on Horizontal Transport • High concentrations of pollutants in a small area (usually due to anthropogenic sources) are the biggest air pollution problems. • The horizontal and vertical transport of air pollutants by winds help control the local concentrations of pollutants. • Concentrations are inversely related to wind speed.

21. Atmospheric Conditions and Air Pollution (2) Effect of Atmospheric Stability • There are many turbulent eddies in an unstable boundary layer, but few in a stable boundary layer • Eddies can mix air vertically. Unstable Neutral Stable

22. Inversions • Inversions are absolutely stable and free of eddies • Inversions can trap pollutants near the Earth’s surface. Low level inversion Upper level inversion (most dangerous)

23. The smog layer in Los Angeles Base of inversions

24. Global effect: Anything released by human beings will be transported globally by atmospheric circulations and ocean circulations

25. Summary • Effects of vegetation: (1) makes heat/water reservoir deeper, (2) enhance evaporation, (3) grows and dies in response to environmental conditions • Effects of different surface types: desert, city, grassland, forest, sea. Deeper heat/water reservoir and enhanced convective instability. • Heat island effect. 7 causes • Air pollution. 2 categories. 6 types of major pollutants (particulates, carbon oxides, sulfur dioxides, nitrogen oxides, volatile organic compounds, ozone) • Effect of wind and stability on pollution: Most dangerous is upper level inversion

26. Works cited • http://www.urbansciences.eu/Descipline.aspx?id=1 • http://www.un.org/esa/population/publications/WUP2005/2005wup.htm