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Chapter 2 Solar Energy to Earth and the Seasons Robert W. Christopherson Charlie Thomsen
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Solar Energy to Earth and the Seasons The Solar System, Sun, and Earth Solar Energy: From Sun to Earth The Seasons
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Milky Way Galaxy Figure 2.1
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Our Solar System Figure 2.1
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Dimensions and Distances Earth’s orbit Average distance from Earth to the Sun is 150,000,000 km (93,000,000 mi) Perihelion – closest distance (at January 3) 147,255,000 km (91,500,000 mi) Aphelion – farthest distance (at July 4) 152,083,000 km (94,500,000 mi) Plane of Earth’s orbit is the plane of the ecliptic
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Solar Energy: From Sun to Earth Electromagnetic spectrum of radiant energy Intercepted energy at the top of the atmosphere-insolation
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Wavelength and Frequency Figure 2.5 Longer wave length, lower frequency, and lower intensity
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The Electromagnetic Spectrum Sun radiates shortwave energy Earth radiates longwave energy
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The Electromagnetic Spectrum of the sun Figure 2.6 Ultra Violet: <0.4μm (8%) Visible light: 0.4-0.7μm (47%) Infra-red: >0.7μmb(45%)
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Solar and Terrestrial Energy Figure 2.7
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Earth’s Energy Budget Figure 2.8 Insolation: intercepted solar radiation Solar constant: average value of the insolation received at the top of the atmosphere when earth is at its average distance from the sun
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Distribution of Insolation Tropics receive more concentrated insolation due to Earth’s curvature (higher solar angles) Tropics receive 2.5times more than poles
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Figure 2.9
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The higher the solar angle, the stronger intensity of solar radiation Direct rays: perpendicular to the earth’s surface. The highest solar angle. Direct rays only occur between Tropic of Cancer (23.5N) and Tropic of Capricorn (23.5S). Subsolar point: the only point (latitude) on the earth’s surface that receives direct rays Sun’s inclination: latitude of the subsolar point
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The Seasons Seasonality Reasons for seasons Annual march of the seasons
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Seasonality Seasonal changes in 1. Sun’s altitude – angle above horizon 2. Declination – location of the subsolar point 3. Daylength
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Reasons for Seasons 1.Revolution 2.Rotation 3.Tilt of Earth’s axis 4.Axial parallelism
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Revolution and Rotation Figure 2.13
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Reasons for Seasons 1. Revolution-length of the year Earth revolves around the Sun Voyage takes one year Earth’s speed is 107,280 kmph (66,660 mph) 2. Rotation-length of the day Earth rotates on its axis once every 24 hours Rotational velocity at equator is 1674 kmph (1041 mph)
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Axial Tilt and Parallelism Figure 2.14 (Circle of illumination)
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Reasons for Seasons Tilt of Earth’s axis Axis is tilted 66.5° from plane of ecliptic Axial parallelism Axis maintains alignment during orbit around the Sun North pole points toward the North Star (Polaris)
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Annual March of the Seasons Figure 2.15
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Annual March of the Seasons Winter solstice – December 21 or 22 Subsolar point Tropic of Capricorn; shortest daylight hours in NH. Spring equinox – March 20 or 21 Subsolar point Equator; equal daylight and night hours everywhere on the earth Summer solstice – June 20 or 21 Subsolar point Tropic of Cancer; Longest daylight hours in NH Fall equinox – September 22 or 23 Subsolar point Equator; equal daylight and night hours
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11:30 P.M. in the Antarctic Figure 2.16
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Midnight Sun Figure 2.17
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Seasonal Observations Figure 2.18
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If the tilted angle is 60 degrees to the plane of ecliptic, where would be tropics and circles? Arctic/antarctic circle=titled angle (60ºN/S) Tropics = 90-titled angle (30ºN/S) Increased tropics area and increased polar areas Larger seasonal variations in most places
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If the tilted angle is 90 degree to the plane of ecliptic? Circles would be at 90ºN/S Tropics would be at equator No seasonal variation No day length changes
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