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Earth ’ s Energy Budget

Earth ’ s Energy Budget. Variations of energy in and out of the Earth in space and time The roles of Earth's tilt, revolution, & rotation in causing spatial, seasonal, & daily temperature variations. Planetary Energy Balance. Energy In = Energy Out. But the observed T s is about 15° C.

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Earth ’ s Energy Budget

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  1. Earth’s Energy Budget Variations of energy in and out of the Earthin space and time The roles of Earth's tilt, revolution, & rotation in causing spatial, seasonal, & daily temperature variations

  2. Planetary Energy Balance Energy In = Energy Out But the observed Ts is about 15° C

  3. What’s Missingfrom the 0-D energy balance model? • Vertical structure The “greenhouse effect” • Energy storage and transport The “general circulation” of the atmosphere and oceans

  4. Atmosphere is Warmed from Below Solar radiation passes first through the upper atmosphere, but only after absorption by earth's surface does it generate sensible heat to warm the ground and generate longwave energy. This heat and energy at the surface then warms the atmosphere from below.

  5. Earth-Atmosphere Energy Balance Earth's surface absorbs the 51 units of shortwave and 96 more of longwave energy units from atmospheric gases and clouds. These 147 units gained by earth are due to shortwave and longwave greenhouse gas absorption and emittance. Earth's surface loses these 147 units through convection, evaporation, and radiation.

  6. Vertical Structure is Crucial • The world is a big place, but the atmosphere is very thin, and most of it is close to the ground • About 15% of the atmosphere is below our feet • At the top of Long’s Peak, the figure is 40% • You are closer to outer space than you are to Denver! • Changes in atmospheric temperature with height are responsible for the “Greenhouse Effect,” which keeps us from freezing to death

  7. Vertical Structure of the Air

  8. The Job of the Atmosphereis to let the energy out! “Piles up” in tropics “Escapes” near poles and aloft The movement of the air (and oceans) allows energy to be transported to its “escape zones!”

  9. Energy In • Meridional gradient • Land-sea contrast • Ice and snow • Deserts vs forests Annual Mean

  10. Energy Out • Given by esT4 (which T?) • Combined surface and atmosphere effects • Decreases with latitude • Maxima over subtropical highs (clear air neither absorbs or emits much) • Minima over tropical continents (cold high clouds) • Very strongmaxima over deserts (hot surface, clear atmosphere) Annual Mean

  11. Energy In minus Energy Out • Incoming solar minus outgoing longwave • Must be balanced by horizontal transport of energy by atmosphere and oceans!

  12. Earth's Energy Balance Earth's annual energy balance between solar insolation and terrestrial infrared radiation is achieved locally at only two lines of latitude A global balance is maintained by transferring excess heat from the equatorial region toward the poles

  13. It Takes a Lot of Energyto Evaporate Water!

  14. Energy Balance of Earth’s Surface H LE shortwave solar radiation longwave (infrared) radiation rising warm air evaporated water Radiation Turbulence Rs

  15. Energy from the Surface to the Air Rising Warm Air (H) • Energy absorbed at the surface warms the air • Some of this energy is transferred in rising warm “thermals” • But more of it is “hidden” in water vapor Evaporated Water (LE)

  16. Seasons • Seasons are regulated by the amount of solar energy absorbed at Earth’s surface • The solar energy received at the top of the atmosphere depends on: • angle at which sunlight strikes Earth’s surface. • how long the sun shines per day • Seasons are NOT due to the elliptical shape of the earth’s orbit.

  17. Seasons & Sun's Distance Figure 3.1 Earth is 5 million kilometers further from the sun in July than in January, indicating that seasonal warmth is controlled by more than solar proximity.

  18. Seasons & Solar Intensity Solar intensity, defined as the energy per area, governs Earth's seasonal climate changes A sunlight beam that strikes at an angle is spread across a greater surface area, and is a less intense heat source than a beam impinging directly.

  19. Solstice & Equinox • Earth's tilt of 23.5° and revolution around the sun creates seasonal solar exposure and heating patterns • At solstice, tilt keeps a polar region with either 24 hours of light or darkness • At equinox, tilt provides exactly 12 hours of night and 12 hours of day everywhere

  20. Midnight Sun The region north of the Arctic Circle experiences a period of 24 hour sunlight in summer, where the Earth's surface does not rotate out of solar exposure

  21. NH summer June 21 Equinox March 20, Sept 22 NH winter Dec 21

  22. Daily Sunshine at Top of Atmosphere • 75º N in June gets more sun than the Equator! • Compare N-S changes by seasons • Very little tropical seasonality

  23. Questions to Think About • Since polar latitudes receive the longest period of sunlight during summer, why aren’t temperatures highest there? • Why aren’t temperatures highest at the summer solstice? • What would happen if we changed the tilt of the earth? • Would we get a more/less pronounced seasonal cycle in the NH if the tilt was increased? • What would happen if the tilt was 90 degrees? 0 degrees?

  24. Regional Seasonal Cycles Regional differences in temperature, from annual or daily, are influenced by geography, such as latitude, altitude, and nearby water or ocean currents, as well as heat generated in urban areas San Francisco is downwind of the Pacific Ocean Richmond, VA is downwind of North America!

  25. Daily Temperature Variations • Each day is like a mini seasonal cycle • Sun rays most intense around noon • As is the case with the seasons, the maximum temperatures lag the peak incoming solar radiation. • An understanding of the diurnal cycle in temperature requires an understanding of the different methods of atmospheric heating and cooling: • Radiation • Conduction • Convection

  26. What Controls Daily High Temperatures? • Tmax depends on • Radiation (Cloud cover) • Surface type • Absorption characteristics • Strong absorbers enhance surface heating • Vegetation/moisture • Available energy partially used to evaporate water • Wind • Strong mixing by wind will mix heated air near ground to higher altitudes

  27. Local Solar Changes Northern hemisphere sunrises are in the southeast during winter, but in the northeast in summer Summer noon time sun is also higher above the horizon than the winter sun

  28. Landscape Solar Response South facing slopes receive greater insolation, providing energy to melt snow sooner and evaporate more soil moisture. North and south slope terrain exposure often lead to differences in plant types and abundance.

  29. Atmospheric Heating by Convection • Sunlight warms the ground • Ground warms adjacent air by conduction • Poor thermal conductivity of air restricts heating to a few cm • Hot air forms rising air “bubbles” (thermals) leading to convection … heats the air, but cools the surface! • Mechanical mixing due to wind enhances this mode of heat transport

  30. Temperature Lags Radiation Earth's surface temperature is a balance between incoming solar radiation and outgoing terrestrial radiation. Peak temperature lags after peak insolation because surface continues to warm until infrared radiation exceeds insolation.

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