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Chapter 3
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Why the Earth has seasons Earth revolves in elliptical path around sun every 365 days. Earth rotates counterclockwise or eastward every 24 hours. Earth closest to Sun (147 million km) in January, farthest from Sun (152 million lm) in July. Distance not the only factor impacting seasons.
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Why the Earth has seasons The amount of energy that reaches the Earths surface is influence by the distance from the Sun, the solar angle, and the length of daylight. When the Earth tilts toward the sun in summer, higher solar angles and longer days equate to high temperatures.
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Why the Earth has seasons Seasons in the Northern Hemisphere Summer solstice: June 21, Sun directly above Tropic of Cancer, Northern Hemisphere days greater than 12 hours Winter solstice: December 21, Sun directly above Tropic of Capricorn, Northern Hemisphere days less than 12 hours Autumnal and Spring Equinox: September 22, Marc 20, Sun directly above Equator, all locations have a 12 hour day
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Stepped Art Fig. 3-8, p. 63
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Why the Earth has seasons Special Topic: First day of winter December 21 is the astronomical first day of winter, sun passes over the Tropic of Capricorn; not based on temperature.
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Why the Earth has seasons Seasons in the Southern Hemisphere Opposite timing of Northern Hemisphere Closer to sun in summer but not significant difference from north due to: ○ Greater amount of water absorbing heat ○ Shorter season
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Simplified Surface Energy Balance NET R = + SW (insolation) – SW (reflection) + LW (infrared) – LW (infrared) Figure 3.13
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Local temperature variations Southern exposure: warmer, drier locations facing south. Implications for Vegetation Viniculture Ski slopes Landscaping Architecture
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Local temperature variations Environmental Issues: Solar Heating In order to collect enough energy from solar power to heat a house, the roof should be perpendicular to the winter sun. For the mid-latitudes the roof slant should be 45°- 50°
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Daily temperature variations Each day like a tiny season with a cycle of heating and cooling Daytime heating Air poor conductor so initial heating only effects air next to ground As energy builds convection begins and heats higher portions of the atmosphere After atmosphere heats from convection high temperature 3-5PM; lag in temperature
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Daily temperature variations Properties of soil affect the rate of conduction from Earth to atmosphere Wind mixes energy into air column and can force convection.
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Daily temperature variations Nighttime cooling As sun lowers, the lower solar angle causes insolation to be spread across a larger area Radiational cooling as infrared energy is emitted by the Earth’s surface Radiation inversion: air near ground much cooler than air above Thermal belt
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Stepped Art Fig. 3-14, p. 69
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Daily temperature variations Protecting crops from cold Cover Smudge pots Fans Sprinklers
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The controls of temperature Latitude: solar angle and day length Land & water: specific heat Ocean currents: warm and cold currents Elevation: cooling and increase range
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Land–Water Heating Differences Evaporation Transparency Specific heat Movement Ocean currents and sea surface temperatures Marine vs. continental effects
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Land–Water Heating Differences Figure 3.20
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Global Temperature Ranges Figure 3.28
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Air temperature data Daily, monthly, yearly temperature Range: maximum minus minimum Mean: average of temperature observations Maximum: highest temperature of time period Minimum: lowest temperature of time period
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Air temperature data Special topic: What’s normal? Climate normal is the 30 year average for a given temperature variable.
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Air temperature data The use of temperature data Heating degree-day: people heat when temperature below 65°F Cooling degree-day: people cool when temperature above 65°F Growing degree-day: temperature above of below base temperature for specific crop
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Air temperature and human comfort Body heats through metabolism wind-chill index Hypothermia Body cools through emitting infrared energy and evaporation of perspiration
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Wind Chill Table Figure 1
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Heat Index Table Figure 2
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Air temperature and human comfort Observation: 1000 degrees Thin air at the top of the atmosphere does not have enough molecules to create a high temperature as measured by a thermometer.
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The Urban Environment Figure 3.29
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Measuring air temperature Thermometers: liquid-in-glass, maximum, minimum, electrical resistance, bimetallic ASOS Thermistors Infrared sensors
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Urban Heat Island Figure 3.30
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Measuring air temperature Observation: Thermometers in the shade Radiant energy from the Sun in direct sunlight increases the temperature recorded by a sensor. True air temperature measured in the shade.
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