Energy and Radiation in Natural Environments

Natural Environments: The Atmosphere GG 101 – Spring 2005 Boston University Myneni Lecture 05: Energy and Radiation Jan-31-05 (1 of 9) Further Reading: Chapter 04 of the text book Outline - matter and energy - radiation laws - solar and terrestrial radiation

Natural Environments: The Atmosphere GG 101 – Spring 2005 Boston University Myneni Lecture 05: Energy and Radiation Jan-31-05 (2 of 9) Introduction • Discussed how energy from the sun reaches the earth and how the orbit of the earth • affects how much energy hits a certain point on the surface • Now we want to discuss what this energy does once it reaches the earth: Need to • understand how energy interacts with matter • So, what is matter? And, what is energy?

Natural Environments: The Atmosphere GG 101 – Spring 2005 Boston University Myneni Lecture 05: Energy and Radiation Jan-31-05 (3 of 9) Matter • Substance that occupies space and has mass • Composed of atoms and molecules • Gas: • Atoms/molecules are spread very far apart • Exhibit random motion relative to their neighbors • Gases expand and compress easily • Liquid: • Atoms/molecules exhibit random motion relative to their neighbors • Interactions with one another • Liquids do not expand and compress easily: allows the travel of waves • Maintains a closed surface even without a container • Solid: • Atoms/molecules in fixed arrangement to one another • Solids do not compress • Bonds can be broken given sufficient energy • State of material depends upon the amount of internal energy in the material • Changing the energy can change its state

Natural Environments: The Atmosphere GG 101 – Spring 2005 Boston University Myneni Lecture 05: Energy and Radiation Jan-31-05 (4 of 9) Energy “Ability to do work” • Electromagnetic radiation: • Energy which travels in waveform • Does not require a medium • Mechanical Energy: • Kinetic Energy - Energy associated with bodies (or atoms) in motion • Potential Energy - Energy associated with the position of a body (or atom) • Atmosphere and oceans have both kinetic energy (due to their motions) and potential energy • (due to their location) • Sensible heat: • Energy associated with motions of atoms/molecules within a larger body • Also called internal kinetic energy • When we measure “temperature” we are actually measuring the internal kinetic energy: as • energy increases -> molecules move faster-> temperature increases • Latent Heat: • Energy associated with the change of phase (or state) of a body • Also related to the energy of the atoms in a larger body (i.e. kinetic energy): as energy • increases -> molecules move faster -> phase changes • Does not result to change in temperature

Natural Environments: The Atmosphere GG 101 – Spring 2005 Boston University Myneni Lecture 05: Energy and Radiation Jan-31-05 (5 of 9) Latent Heat The Movie • Solid -> liquid -> Gas • Internal Kinetic energy increases • Requires input of energy • Conversion of any kind of energy into latent heat • Gas -> Liquid -> Solid • Internal kinetic energy decreases • Releases energy • Conversion of latent heat into energy (typically • sensible heat) • Or loss of energy (i.e. loss of energy from water • to environment produces ice) • Conversion of one form of water to another is a critical mechanism • for transferring heat with the atmosphere

Natural Environments: The Atmosphere GG 101 – Spring 2005 Boston University Myneni Lecture 05: Energy and Radiation Jan-31-05 (6 of 9) Radiation Energy Animation: EM-Wave • Key Properties: • All matter emits radiation (as long as it has a • temperature and all matter has a temperature) • Travels in waveform • Characteristics of the waveform determines how much • energy the radiation has • Energy can travel through vacuum • Wavelength is the distance between two successive • peaks or lows (frequency is inverse of wavelength) Short wavelengths = higher energy Long wavelengths = lower energy

Natural Environments: The Atmosphere GG 101 – Spring 2005 Boston University Myneni Lecture 05: Energy and Radiation Jan-31-05 (7 of 9) Stefan-Boltzmann Law (Visualization) Relates the total flux of energy per unit area emitted by a body to its temperature (the higher the temperature, the more the energy emitted) Energy flux: W/m2 Stefan-Boltzmann constant (5.67 x 10-8 W/m2/K4) Temperature K (kelvin) • Example • Sun: • T = 6000 K  m = 70,000,000 W/m2 • Earth: • T = 300 K  m = 450 W/m2

Natural Environments: The Atmosphere GG 101 – Spring 2005 Boston University Myneni Lecture 05: Energy and Radiation Jan-31-05 (8 of 9) Wein’s Law Computes the wavelength of the most intense radiation as a function of temperature (the higher the temperature, the shorter the wavelength of maximum emission) Wavelength: (micrometers) Temperature (K) • Example • Sun: • T = 6000 K  l = 0.48 mm (0.00000048 m) • Earth: • T = 300 K  l = 9.6 mm (0.0000096 m)

Natural Environments: The Atmosphere GG 101 – Spring 2005 Boston University Myneni Lecture 05: Energy and Radiation Jan-31-05 (9 of 9) Short and Longwave Radiation • Bodies with higher temperature emit: • More energy • Shorter wavelengths • More specifically:a body emits energy at many wavelengths; how much energy at each wavelength depends on the temperature of the body • Sun (Solar Radiation): • higher peak -> more intense radiation • shortwave (0.2-4 micrometers) • ultra-violet (0.2-0.4 mm) visible (0.4-0.7 mm) • and shortwave infrared (0.7-4.0 mm) • Earth (Terrestrial Radiation): • low peak -> less intense radiation • longwave (4-50 micrometers) • thermal

Energy and Radiation in Natural Environments

Energy and Radiation in Natural Environments

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