1. Fire Behavior

2. Photosynthesis

3. Biomass is Destroyed

7. Four Phases of Combustion Process 1). Pre-ignition Heat is required to raise a fuel to ignition temperature (600 degrees F)

8. Four Phases of Combustion Process 2). Ignition Process where a rapid, exothermic reaction is initiated, which causes the material to undergo changes, producing temperatures greatly in excess of the ambient (Drysdale 1985).

9. Four Phases of Combustion Process 3). Combustion Flaming=volatiles that are produced in the preheating phase ignite to form a visible flame Smoldering=the remaining carbon may burn as a solid by surface oxidation

10. Four Phases of Combustion Process 4). Extinction Opposite of ignition (termination of combustion) Moisture content of fuel can play a large role

11. SMOKE incomplete combustion where volatile products remain suspended as very small droplets of liquid plus residual carbonized particles that float in the air

14. Fire intensity-the rate at which a fire releases heat energy Energy released/unit area/time (Btu/ft/sec)

17. BEHAVE FIRE MODEL

18. 3 Basic Types of Fire Behavior

20. Fire Behavior Terminology 1). Running 2). Creeping 3). Smoldering 4). Spotting

21. Fire Behavior Terminology 5). Torching 6). Crowning 7). Flare-up 8). Blowup

23. Topography-- Slope Position

24. Front Fire Backing Fire

25. Topography-- Slope Steepness

27. Pinyon-Juniper Ponderosa Pine Mixed Conifer Spruce/Fir Alpine North South 5,000 ft 6,000 ft 7,000 ft 8,000 ft 9,000 ft 10,000 ft 11,000 ft 12,000 ft 13,000 ft 14,000 ft Topography-- Aspect and Elevation

28. Aspect SOUTH NORTH Heavy fuels Shade Moist Light fuels Sunny Dry

29. Topography-- Barriers

30. Topography-- Box Canyon Chimney Effect- Occurs when unstable air conditions at the surface create a convection current through the canyon, drawing air in at the base of the canyon and exhausting it at the top

31. Radiant Heat Across Narrow Canyon

32. Spotting Across Narrow Canyon

33. 1. insolation—solar radiation that is intercepted by Earth (surface and atmosphere) Influenced by: a) angle of incoming radiation b) length of time exposure Weather-Temperature

34. patterns of heat gain/loss daily Midnight 6 noon 6 Midnight Coolest time Hottest time-maximum amount absorbed Temp Energy Flow

35. Spatial patterns on heat/cold Day Night warm cold Weather-Temperature

36. The amount of humidity the air can hold at a specific temperature compared to the amount that it is actually holding is called the relative humidity. Weather-Relative Humidity

37. Red line is fuel moisture--note lag time

38. WINDWARDLEEWARD Rainshadow Dewpoint Chinook Winds Adiabatic lapse rate-change in temperature with altitude due to pressure

39. Weather-Air Stability

40. Weather-Wind/Storm Relationships

41. Weather-Wind horizontal movement of air

42. Weather-Types of Wind

44. Mountains Cause Channeling of Wind

45. Convection Column- rapidly rising superheated smoke can soar 35,000 feet or higher into the atmosphere and cause a rapid indraft of cooler air to the fire on the ground Weather-Fire

48. El Nino is a disruption of the ocean- atmosphere system in the tropical Pacific that has implications for weather around the globe

50. 1) Fuel-Quantity Ways to Classify Fuels: Oven dry weight of fuels in a given area

51. 2) Fuel-Size and Shape

52. Duff is the organic forest horizons (fermentation and humus layers) that accumulate above the mineral soil

53. Litter is the surface layer consisting of freshly fallen leaves, needles, twigs, stems, and bark.

54. 3) Fuel-Arrangement

55. Uniform Fuels

56. Patchy Fuels

57. Ladder Fuels

58. 4) Fuel-Components 3) GROUND 2) SURFACE 1) AERIAL

60. How are fuels characterized? 1) Direct-sampling 2) Planar transect 3) Photo guides 4) Prediction models

63. Fuel-Moisture Content

64. Fuel moisture- percent of dry weight of fuel Live fuel moisture- can range from 1-over 100 percent Dead fuel moisture- often below 10 percent

65. Timelag Intervals-time required to lose 63 percent (2/3) of difference between original moisture content and equilibrium moisture content at a constant temperature and relative humidity

67. Fuel changes over time 1) Abrupt 2) Diurnal 3) Seasonal 4) Annual

73. Unusually dry fuels. Large amount of light fuel (shrubs, grass, needles). Fuels exposed to direct sunlight. Fuels dried by prolonged drought. Ladder fuels that allow a surface fire to move into the crowns of shrubs or trees. Crown foliage dried by surface fire. Concentration of snags. Indicators of Problem and Extreme Fire Behavior Fuel Indicators

74. Indicators of Problem and Extreme Fire Behavior Steep slopes. Chutes, saddles, and box canyons which provide conditions for “chimney effect.” Narrow canyons may increase fire spread by radiant heat and spotting. Topography Indicators

75. Strong Wind. Sudden changes in wind direction and velocity due to weather fronts. High, fast-moving clouds may indicate unusual surface winds. Unexpected calm may indicate wind shift. Thunderstorms above or close to the fire. Unusually high temperatures and low relative humidity. Dust devils and whirlwinds developing. Bent smoke column. Indicators of Problem and Extreme Fire Behavior Weather Indicators

76. Keep an eye on the smoke column. Indicates direction of fire spread, location of spot fires, and changes in fire intensity. Many simultaneous fires starting or smoldering fires beginning to pick up in intensity. Fire begins to torch small groups of trees or shrubs. Frequent spot fires occurring. Firewhirls beginning to develop inside the main fire. Crown fires. Indicators of Problem and Extreme Fire Behavior Fire Behavior Indicators