Lecture 4

1. Lecture 4 More about Temperature

2. Incoming vs. Outgoing Radiation

3. Controls of Temperature • Latitude • Land and Water • Ocean Currents • Elevation

4. Average Temperature in January

5. Average Temperature in July

7. Contouring EXAMPLE

8. Contouring

9. Contouring

10. Daytime Warming On a clear, windless day, joggers may experience a temperature of 122oF near their feet, and a temperature of 90oF near their waist.

11. Daytime Warming

12. Peak Temperature

13. Nighttime Cooling

14. Radiation Inversion Ingredients • Windless night • Wind mixes the air with turbulent eddies • A long night • Cloudless night • Clouds radiate infrared energy back to surface • A dry night • If dew forms, then latent heat of condensation is released.

15. Radiational Inversion

16. Daily Low Temperature • The lowest temperature may be reached after sunrise. Why? • After sunrise outgoing energy still exceeds incoming. • The solar angle is low at sunrise • If there is moisture, then evaporation cools the air.

17. Peak Temperature

18. How do we protect crops from freezing?

19. How do we protect crops from freezing?

20. Diurnal Range

21. Heating Degree-Day

22. Cooling Degree-Day

23. Growing Degree-Day

24. Mean Annual Temperature

25. Measuring Temperature

26. Measuring Temperature • Liquid in Glass Thermometers (mercury or alcohol) • Electric Thermometers (used in Automated Weather Stations) • Thermocouples • Platinum Resistance Thermometers • Radiometers (on satellites, weather balloons) • Bimetallic Thermometer (thermographs)

27. Wind Chill Why doe the wind make it feel colder? • On cold days our body warms a thin layer of air around us. • When the wind blows, this warm layer is replaced by cold air. • The faster the wind blows the colder we feel.

28. The wind chill equivalent temperature tells us how cold it would have to be with no wind, in order for us to lose the same amount of heat. • This is new as of 2001! • - Replaces Paul Siple’s original work in Antarctica • - A bit “warmer” than the old formula • -Will be updated in the near future for sunshine

29. Controls of Temperature • Latitude • Land and Water • Ocean Currents • Elevation

30. Urban Heat Island Stanley Park Downtown Vancouver

32. Urban Heat island • Decrease in: • Wind speed • Humidity (drainage systems take away water!) • Increase in: • Temperatures • Cloudiness • Precipitation • Fog • Pollution

33. Causes of Urban Heat Island • Surfaces • Low albedos of asphalt and concrete • Heat trapping • Tall structures reflect and absorb outgoing radiation • Lack of water (rapid water run-off) • Less water  less evaporative cooling • Surface friction • Low wind speed  less mixing

34. Causes of Urban Heat Island • Human produced heat • In buildings, automobiles • Particulates and Smog • Greenhouse enhancer, traps heat • Snow Removal • Decreases the albedo

35. Heat Island Example Areas that are “warm” appear in white/light gray. Areas that are “cool” appear dark. Atlanta

36. Heat Island Example Trees and vegetation appear in red. Buildings, streets and urban land cover is white/blue-green/black. Note the shape of the downtown region. Atlanta

37. Heat Island Example Remember the shape of the downtown!

38. Heat Trapping