Properties

There are four main properties that characterize thermal radiation:

Thermal radiation, even at a single temperature, occurs at a wide range of frequencies. How much of each frequency is given by Planck law of radiation (for idealized materials). This is shown by the curves in the diagram at right.

The main frequency (or color) range of the emitted radiation includes higher and higher frequencies as the temperature increases. For example, a red hot object radiates enough in the long wavelengths (red and orange) of the visible band to see, which is why it appears red. If it heats up further, it also begins to emit discernible amounts of green and blue light, and the spread of frequencies mentioned in the first point make it appear white. We then say the object is white hot. However, even at a "white-hot" temperature of 2000 K, 99% of the energy of the radiation is still in the infrared. This is related to Wien's displacement law. In the diagram the peak value for each curve moves to the left as the temperature increases.

The total amount of radiation, of all frequencies, goes up very fast as the temperature rises (it grows as T4, where T is the absolute temperature of the body). An object at the temperature of a kitchen oven (about twice room temperature in absolute terms: 600 K vs. 300 K) radiates 16 times as much power per unit area. An object at the temperature of the filament in an incandescent bulb (roughly 3000 K, or 10 times room temperature) radiates 10,000 times as much per unit area. The total radiative intensity in a cavity that contains a black body in thermodynamic equilibrium rises as the fourth power of the absolute temperature, the Stefanoltzmann law. In the plot, the area under each curve rises rapidly as the temperature increases.

These properties apply if the distances considered are much larger than the wavelengths contributing to the spectrum (most significant from 8-25 micrometres at 300 K). Indeed, thermal radiation here takes only travelling waves into account. A more sophisticated framework involving electromagnetics has to be used for lower distances (near-field thermal radiation).

C

Subjective colour

480

faint red glow

580

dark red

730

bright red, slightly orange

930

bright orange

1100

pale yellowish orange

1300

yellowish white

> 1400

white (yellowish if seen from a distance through atmosphere)

Interchange of energy

Radiant heat panel for testing precisely quantified energy exposures at National Research Council, near Ottawa, Ontario, Canada.

Thermal radiation is an important concept in thermodynamics as it is partially responsible for heat exchange between objects, as warmer bodies radiate more heat than colder ones. (Other factors are convection and conduction.) The interplay of energy exchange is characterized by the following equation:

Here, represents spectral absorption factor, spectral reflection factor and spectral transmission factor. All these elements depend also on the wavelength . The spectral absorption factor is equal to the emissivity ; this relation is known as Kirchhoff's law of thermal radiation. An object is called a black body if, for all frequencies, the following formula applies:

In a practical situation and room-temperature setting, humans lose considerable energy due to thermal radiation. However, the energy lost by emitting infrared heat is partially regained by absorbing the heat of surrounding objects (the remainder resulting from generated heat through metabolism). Human skin has an emissivity of very close to 1.0 . Using the formulas below then shows a human being, roughly 2 square meter in area, and about 307 kelvins in temperature, continuously radiates about 1000 watts. However, if people are indoors, surrounded by surfaces at 296 K, they receive back about 900 watts from the wall, ceiling, and other surroundings, so the net loss is only about 100 watts. These heat transfer estimates are highly dependent on extrinsic variables, such as wearing clothes (decreasing total thermal "circuit" conductivity, therefore reducing total output heat flux.) Only truly "grey" systems (relative equivalent emissivity/absorptivity and no directional transmissivity dependence in all control volume bodies considered) can achieve reasonable steady-state heat flux estimates through the Stefan-Boltzmann law. Encountering this "ideally calculable" situation is virtually impossible (although common engineering procedures surrender the dependency of these unknown variables and "assume" this to be the case). Optimistically, these "grey" approximations will get you close to real solutions, as most divergence from Stefan-Boltzmann solutions is very small (especially in most STP lab controlled environments).

If objects appear white (reflective in the visual spectrum), they are not necessarily equally reflective (and thus non-emissive) in the thermal infrared; e. g. most household radiators are painted white despite the fact that they have to be good thermal radiators. Acrylic and urethane based white paints have 93% blackbody radiation efficiency at room temperature (meaning the term "black body" does not always correspond to the visually perceived color of an object). These materials that do not follow the "black color = high emissivity/absorptivity" caveat will most likely have functional spectral emissivity/absorptivity dependence.

Calculation of radiative heat transfer between groups of object, including a 'cavity' or 'surroundings' requires solution of a set of simultaneous equations using the Radiosity method. In these calculations, the geometrical configuration of the problem is distilled to a set of numbers called view factors, which give the proportion of radiation leaving any given surface that hits another specific surface. These calculations are important in the fields of solar thermal energy, boiler and furnace design and raytraced computer graphics.

Formula

Thermal radiation power of a black body per unit of area, unit of solid angle and unit of frequency is given by Planck's law as:

or

where is a constant.

This formula mathematically follows from calculation of spectral distribution of energy in quantized electromagnetic field which is in complete thermal equilibrium with the radiating object.

Integrating the above equation over the power output given by the Stefanoltzmann law is obtained, as:

where the constant of proportionality is the Stefanoltzmann constant and A is the radiating surface area.

Further, the wavelength , for which the emission intensity is highest, is given by Wien's Law as:

For surfaces which are not black bodies, one has to consider the (generally frequency dependent) emissivity factor (). This factor has to be multiplied with the radiation spectrum formula before integration. If it is taken as a constant, the resulting formula for the power output can be written in a way that contains as a factor:

This type of theoretical model, with frequency-independent emissivity lower than that of a perfect black body, is often known as a gray body. For frequency-dependent emissivity, the solution for the integrated power depends on the functional form of the dependence, though in general there is no simple expression for it. Practically speaking, if the emissivity of the body is roughly constant around the peak emission wavelength, the gray body model tends to work fairly well since the weight of the curve around the peak emission tends to dominate the integral.

Constants

Definitions of constants used in the above equations:

Planck's constant

6.626 0693(11)1034 Js = 4.135 667 43(35)1015 eVs

Wien's displacement constant

2.897 7685(51)103 mK

Boltzmann constant

1.380 6505(24)1023 JK1 = 8.617 343(15)105 eVK1

Stefanoltzmann constant

5.670 400(40)108 Wm2K4

Speed of light

299,792,458 ms1

Variables

Definitions of variables, with example values:

Temperature

Average surface temperature on Earth = 288 K

Surface area

Acuboid = 2ab + 2bc + 2ac;

Acylinder = 2r(h + r);

Asphere = 4r2

See also

Thermography

Infrared photography

Planck radiation

Thermal dose unit

Color temperature

References

^ K. Huang, Statistical Mechanics (2003), p278

^ K. Huang, Statistical Mechanics (2003), p280

^ R. Bowling Barnes (24 May 1963). "Thermography of the Human Body Infrared-radiant energy provides new concepts and instrumentation for medical diagnosis". Science 140 (3569): 870877. doi:10.1126/science.140.3569.870.

^ S. Tanemura, M. Tazawa, P. Jing, T. Miki, K. Yoshimura, K. Igarashi, M. Ohishi, K. Shimono, M. Adachi, Optical Properties and Radiative Cooling Power of White Paints, ISES 1999 Solar World Congress

Related reading:

Siegel, John R. Howell, Robert; Howell. John R. (2001-11). Thermal radiation heat transfer. New York: Taylor & Francis, Inc.. pp. (xix - xxvi list of symbols for thermal radiation formulas). ISBN 9781560328391. http://books.google.com/books?id=O389yQ0-fecC&pg=PA1&dq=Thermal+radiation. Retrieved 2009-07-23.

External links

Free Black Body Emission Calculator

Heat Transfer

Thermal Radiation

Atmospheric Radiation

Infrared Temperature Calibration 101

v d e

Radiation (Physics & Health)

Main articles

Non-ionizing radiation

Ultraviolet light Near ultraviolet Visible light Infrared light Microwave Radio waves Acoustic Radiation

Ionizing radiation

X-ray Cosmic radiation Gamma ray Background radiation Nuclear fission Nuclear fusion Particle accelerators Nuclear radiation (nuclear weapons Nuclear reactors) Radioactive materials (Radioactive decay)

Thermal radiation Electromagnetic radiation Earth's radiation balance

Radiation health effects

Radiation therapy Radiation poisoning Skin effect Radioactivity in biological research List of civilian radiation accidents

Mobile phone radiation and health Wireless electronic devices and health Health physics Laser safety Lasers and aviation safety

Related articles

Radiation hardening Half-life Radiobiology Nuclear physics

See also: Category:Radiation effects Category:Radioactivity Category:Radiation health effects Category:Radiobiology

Categories: Electromagnetic radiation | Heat transfer | ThermodynamicsHidden categories: Articles lacking in-text citations from October 2007 | All articles lacking in-text citations

There are four main properties that characterize thermal radiation:

Thermal radiation, even at a single temperature, occurs at a wide range of frequencies. How much of each frequency is given by Planck law of radiation (for idealized materials). This is shown by the curves in the diagram at right.

The main frequency (or color) range of the emitted radiation includes higher and higher frequencies as the temperature increases. For example, a red hot object radiates enough in the long wavelengths (red and orange) of the visible band to see, which is why it appears red. If it heats up further, it also begins to emit discernible amounts of green and blue light, and the spread of frequencies mentioned in the first point make it appear white. We then say the object is white hot. However, even at a "white-hot" temperature of 2000 K, 99% of the energy of the radiation is still in the infrared. This is related to Wien's displacement law. In the diagram the peak value for each curve moves to the left as the temperature increases.

The total amount of radiation, of all frequencies, goes up very fast as the temperature rises (it grows as T4, where T is the absolute temperature of the body). An object at the temperature of a kitchen oven (about twice room temperature in absolute terms: 600 K vs. 300 K) radiates 16 times as much power per unit area. An object at the temperature of the filament in an incandescent bulb (roughly 3000 K, or 10 times room temperature) radiates 10,000 times as much per unit area. The total radiative intensity in a cavity that contains a black body in thermodynamic equilibrium rises as the fourth power of the absolute temperature, the Stefanoltzmann law. In the plot, the area under each curve rises rapidly as the temperature increases.

These properties apply if the distances considered are much larger than the wavelengths contributing to the spectrum (most significant from 8-25 micrometres at 300 K). Indeed, thermal radiation here takes only travelling waves into account. A more sophisticated framework involving electromagnetics has to be used for lower distances (near-field thermal radiation).

C

Subjective colour

480

faint red glow

580

dark red

730

bright red, slightly orange

930

bright orange

1100

pale yellowish orange

1300

yellowish white

> 1400

white (yellowish if seen from a distance through atmosphere)

Interchange of energy

Radiant heat panel for testing precisely quantified energy exposures at National Research Council, near Ottawa, Ontario, Canada.

Thermal radiation is an important concept in thermodynamics as it is partially responsible for heat exchange between objects, as warmer bodies radiate more heat than colder ones. (Other factors are convection and conduction.) The interplay of energy exchange is characterized by the following equation:

Here, represents spectral absorption factor, spectral reflection factor and spectral transmission factor. All these elements depend also on the wavelength . The spectral absorption factor is equal to the emissivity ; this relation is known as Kirchhoff's law of thermal radiation. An object is called a black body if, for all frequencies, the following formula applies:

In a practical situation and room-temperature setting, humans lose considerable energy due to thermal radiation. However, the energy lost by emitting infrared heat is partially regained by absorbing the heat of surrounding objects (the remainder resulting from generated heat through metabolism). Human skin has an emissivity of very close to 1.0 . Using the formulas below then shows a human being, roughly 2 square meter in area, and about 307 kelvins in temperature, continuously radiates about 1000 watts. However, if people are indoors, surrounded by surfaces at 296 K, they receive back about 900 watts from the wall, ceiling, and other surroundings, so the net loss is only about 100 watts. These heat transfer estimates are highly dependent on extrinsic variables, such as wearing clothes (decreasing total thermal "circuit" conductivity, therefore reducing total output heat flux.) Only truly "grey" systems (relative equivalent emissivity/absorptivity and no directional transmissivity dependence in all control volume bodies considered) can achieve reasonable steady-state heat flux estimates through the Stefan-Boltzmann law. Encountering this "ideally calculable" situation is virtually impossible (although common engineering procedures surrender the dependency of these unknown variables and "assume" this to be the case). Optimistically, these "grey" approximations will get you close to real solutions, as most divergence from Stefan-Boltzmann solutions is very small (especially in most STP lab controlled environments).

If objects appear white (reflective in the visual spectrum), they are not necessarily equally reflective (and thus non-emissive) in the thermal infrared; e. g. most household radiators are painted white despite the fact that they have to be good thermal radiators. Acrylic and urethane based white paints have 93% blackbody radiation efficiency at room temperature (meaning the term "black body" does not always correspond to the visually perceived color of an object). These materials that do not follow the "black color = high emissivity/absorptivity" caveat will most likely have functional spectral emissivity/absorptivity dependence.

Calculation of radiative heat transfer between groups of object, including a 'cavity' or 'surroundings' requires solution of a set of simultaneous equations using the Radiosity method. In these calculations, the geometrical configuration of the problem is distilled to a set of numbers called view factors, which give the proportion of radiation leaving any given surface that hits another specific surface. These calculations are important in the fields of solar thermal energy, boiler and furnace design and raytraced computer graphics.

Formula

Thermal radiation power of a black body per unit of area, unit of solid angle and unit of frequency is given by Planck's law as:

or

where is a constant.

This formula mathematically follows from calculation of spectral distribution of energy in quantized electromagnetic field which is in complete thermal equilibrium with the radiating object.

Integrating the above equation over the power output given by the Stefanoltzmann law is obtained, as:

where the constant of proportionality is the Stefanoltzmann constant and A is the radiating surface area.

Further, the wavelength , for which the emission intensity is highest, is given by Wien's Law as:

For surfaces which are not black bodies, one has to consider the (generally frequency dependent) emissivity factor (). This factor has to be multiplied with the radiation spectrum formula before integration. If it is taken as a constant, the resulting formula for the power output can be written in a way that contains as a factor:

This type of theoretical model, with frequency-independent emissivity lower than that of a perfect black body, is often known as a gray body. For frequency-dependent emissivity, the solution for the integrated power depends on the functional form of the dependence, though in general there is no simple expression for it. Practically speaking, if the emissivity of the body is roughly constant around the peak emission wavelength, the gray body model tends to work fairly well since the weight of the curve around the peak emission tends to dominate the integral.

Constants

Definitions of constants used in the above equations:

Planck's constant

6.626 0693(11)1034 Js = 4.135 667 43(35)1015 eVs

Wien's displacement constant

2.897 7685(51)103 mK

Boltzmann constant

1.380 6505(24)1023 JK1 = 8.617 343(15)105 eVK1

Stefanoltzmann constant

5.670 400(40)108 Wm2K4

Speed of light

299,792,458 ms1

Variables

Definitions of variables, with example values:

Temperature

Average surface temperature on Earth = 288 K

Surface area

Acuboid = 2ab + 2bc + 2ac;

Acylinder = 2r(h + r);

Asphere = 4r2

See also

Thermography

Infrared photography

Planck radiation

Thermal dose unit

Color temperature

References

^ K. Huang, Statistical Mechanics (2003), p278

^ K. Huang, Statistical Mechanics (2003), p280

^ R. Bowling Barnes (24 May 1963). "Thermography of the Human Body Infrared-radiant energy provides new concepts and instrumentation for medical diagnosis". Science 140 (3569): 870877. doi:10.1126/science.140.3569.870.

^ S. Tanemura, M. Tazawa, P. Jing, T. Miki, K. Yoshimura, K. Igarashi, M. Ohishi, K. Shimono, M. Adachi, Optical Properties and Radiative Cooling Power of White Paints, ISES 1999 Solar World Congress

Related reading:

Siegel, John R. Howell, Robert; Howell. John R. (2001-11). Thermal radiation heat transfer. New York: Taylor & Francis, Inc.. pp. (xix - xxvi list of symbols for thermal radiation formulas). ISBN 9781560328391. http://books.google.com/books?id=O389yQ0-fecC&pg=PA1&dq=Thermal+radiation. Retrieved 2009-07-23.

External links

Free Black Body Emission Calculator

Heat Transfer

Thermal Radiation

Atmospheric Radiation

Infrared Temperature Calibration 101

v d e

Radiation (Physics & Health)

Main articles

Non-ionizing radiation

Ultraviolet light Near ultraviolet Visible light Infrared light Microwave Radio waves Acoustic Radiation

Ionizing radiation

X-ray Cosmic radiation Gamma ray Background radiation Nuclear fission Nuclear fusion Particle accelerators Nuclear radiation (nuclear weapons Nuclear reactors) Radioactive materials (Radioactive decay)

Thermal radiation Electromagnetic radiation Earth's radiation balance

Radiation health effects

Radiation therapy Radiation poisoning Skin effect Radioactivity in biological research List of civilian radiation accidents

Mobile phone radiation and health Wireless electronic devices and health Health physics Laser safety Lasers and aviation safety

Related articles

Radiation hardening Half-life Radiobiology Nuclear physics

See also: Category:Radiation effects Category:Radioactivity Category:Radiation health effects Category:Radiobiology

Categories: Electromagnetic radiation | Heat transfer | ThermodynamicsHidden categories: Articles lacking in-text citations from October 2007 | All articles lacking in-text citations

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This article was published on 2011/01/14

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