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Earth Science 17.2 Heating the Atmosphere . Heating the Atmosphere . Heat vs.Temperature . The concepts of heat and temperature are often confused. Heat = energy transferred from one object to another because of a difference in their temperatures.
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Earth Science 17.2 Heating the Atmosphere Heating the Atmosphere
Heat vs.Temperature • The concepts of heat and temperature are often confused. • Heat=energy transferred from one object to another because of a difference in their temperatures. • All matter is composed of atoms or molecules that possess kinetic energy, or the energy of motion. • Temperature=the average kinetic energy of individual atoms or molecules in a substance. Heat Temperature
Heat vs.Temperature • When energy is transferred to the gas atoms and molecules in air, those particles move faster and air temperature rises. • When air transfers energy to a cooler object, its particles move more slowly, and air temperature drops. Heat Temperature
Energy Transfer as Heat • Three mechanisms of energy transfer as heat are • 1) Conduction • 2) Convection • 3) Radiation • All three processes happen simultaneously in our atmosphere. • These mechanisms work to transfer energy between Earth’s surface (both land and water) and the atmosphere.
Energy Transfer as Heat: Conduction Conduction: • Anyone who has touched a hot metal spoon that was left in a pan on a stove has experienced the result of heat conducted through the spoon. • Conduction = the transfer of heat through matter by molecular activity. • The energy of molecules is transferred by collisions from one molecule to another. • Heat flows from the higher temperature matter to lower temperature matter.
Energy Transfer as Heat: Conduction Conduction: • The ability of substances to conduct heat varies greatly. • Metals = good conductors (try touching a hot pan) • Air= very poor conductor • Because air is a poor conductor, conduction is important only between Earth’s surface and air directly in contact with the surface. For our atmosphere, conduction is the least important mechanism of heat transfer.
Energy Transfer as Heat: Conduction Convection: • Much of the heat transfer that occurs in the atmosphere is carried on by convection. • Convection = transfer of heat by mass movement or circulation within a substance. • It takes place in fluids, like the ocean or air, where the atoms and molecules are free to move about.
Energy Transfer as Heat: Convection • A pan of water boiling demonstrates convection currents. • Radiation from a flame warms the bottom of the pan, which conducts heat to the water at the bottom of the pan. • As the water is heated, it expands and becomes less dense than the water above it and it rises. • At the same time, cooler water near the top sinks to the bottom and than becomes heated to start the cycle over again.
Energy Transfer as Heat: Convection • As long as water is heated unequally, from the bottom, it will continue to circulate as hotter water rises and cooler water sinks. • In much the same way, most of the heat acquired by radiation and conduction in the lowest layer of the atmosphere is transferred by heat convection.
Electromagnetic Waves: • The sun is the ultimate source of energy that creates our weather. • You know the sun emits light, heat, & ultraviolet rays that cause a sunburn. • These forms of energy are only a part of a larger array of energy called the electromagnetic spectrum. • All radiation, whether X-rays, radio waves or infrared waves, travels through the vacuum of space at 300,000 km/s. Electromagnetic spectrum
Electromagnetic Waves: • Imagine tossing a pebble in a pond. Ripples are made and move away from the location where the pebble hit the water’s surface in waves. • Like ripples, electromagnetic waves move out from their source and come in various sizes. • Electromagnetic waves are classified by their wavelengths; the distance from the crest of one wave to the crest of the next wave. • Radio waves = the longest wavelengths (to tens of kilometers) • Gamma rays = the shortest wavelengths (less than a billionth of a centimeter long) Electromagnetic spectrum
Electromagnetic Waves: • Visible light is the only portion of these waves we can see. • White light is really a mixture of colors; each color corresponding to a certain wavelength of light. • By using a prism, white light can be divided into the colors of the rainbow; from violetwith the shortest wavelength (.4 micrometers) to redwith the longest wavelength (.7 micrometers). Electromagnetic spectrum
Radiation: • The third mechanism of heat transfer is radiation. • Radiant energy travels out in all directions from it’s source; like heat from a fire. • Unlike conduction and convection, which need material to travel through, radiant energy can travel through the vacuum of space. • Solar energy reaches Earth from the sun by radiation.
Radiation: • To understand how the atmosphere is heated, it is useful to think about 4 laws governing radiation. _________________________ • 1: All objects, at any temperature, emit radiant energy. • Not only hot objects like the sun, but colder objects like the Earth (including it’s polar ice caps) continuously emit energy.
Radiation: • To understand how the atmosphere is heated, it is useful to think about 4 laws governing radiation. _________________________ • 2: Hotter objects radiate more total energy “per unit area” than colder objects do.
Radiation: • To understand how the atmosphere is heated, it is useful to think about 4 laws governing radiation. _________________________ • 3: The hottest radiating bodies produce the shortest wavelengths of maximum radiation. • For example, the sun, with a surface temperature of nearly 6000 degrees Celsius radiates maximum energy at .5 micrometers, which is in the visible range.
Radiation: • To understand how the atmosphere is heated, it is useful to think about 4 laws governing radiation. _________________________ • 4: A good absorber of radiation = a good emitter as well. • Gases are selective absorbers and radiators. The atmosphere does not absorb certain wavelengths of radiation, but it is a good absorber of other wavelengths.
Radiation: • When radiation strikes an object, there are usually three different results. • 1: Some energy is absorbed by the object. When radiant energy is absorbed, it is converted to heat and causes a temperature increase. • 2: Substances such as water and air are transparent to certain wavelengths of radiation. These substances transmit the radiant energy. Radiation that is transmitted does not contribute energy to the object. • 3: Some radiation may bounce off the object without being absorbed or transmitted.
Reflecting and Scattering: • Reflection = when an electromagnetic wave bounces off an object. • The reflected radiation has the same intensity as the initial (incident) radiation. • In contrast, scattering produces a larger number of weaker rays that travel in different directions. Scattering disperses waves in all directions. • Most solar radiant energy is dispersed in the forward direction but about 30% of the solar energy is reflected back into space. • This Energy is lost and does not heat Earth’s atmosphere.
Reflecting and Scattering: • Small dust particles and gas molecules in the atmosphere scatter incoming radiation in all directions. • This explains how light reaches into the area under a shade tree, and how a room is lit in the absence of direct sunlight. • Scattering also accounts for the brightness and even the blue color of the daytime sky. • About half the solar radiation that is absorbed by Earth arrives as scattered radiation.
Absorption: • About 50 percent of the solar energy that strikes the top of the atmosphere reaches Earth’s surface and is absorbed. • Most of this energy is than reradiated skyward. • The atmosphere efficiently absorbs the longer wavelengths emitted by the Earth. • Water vapor and carbon dioxide are the major absorbing gases. • When a gas molecule absorbs those waves, this energy is transformed into molecular motion that can be detected as a rise in temperature.
Absorption: • Gases in the atmosphere eventually radiate some of this energy away. • Some energy travels skyward, where it may be reabsorbed by other gas molecules. • The rest travels earthward and is again absorbed. • In this way, Earth’s surface is continually supplied with heat from the atmosphere as well as from the sun.
Absorption: • Without these absorbing gases in our atmosphere, Earth would not be a suitable habitat for most type of living things on the Earth today. • This phenomena has been termed the greenhouse effect because it was once thought that greenhouses were heated in a similar manner. • There is a balance of energy transfer into and out of Earth’s atmosphere. • Over time, incoming solar radiation is absorbed, reflected, or reradiated. • As a result, the atmosphere’s average temperature tends to remain constant from year to year. But the atmosphere’s average temperature can change in response to factors that disturb the energy balance of this exchange.
Photosynthesis • Some incoming solar radiation is not absorbed and reradiated. • Instead , it is absorbed by the chlorophyll in green plants. • Plants use the energy from this radiation in photosynthesis. • Thus solar energy is the main energy source for virtually all life on Earth.