Vlasov equation: Difference between revisions
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In various scientific contexts, a '''scale height''' is a distance over which a quantity decreases by a factor of ''[[e (mathematical constant)|e]]'' (approximately 2.71828, the base of [[natural logarithms]]). It is usually denoted by the capital letter ''H''. | |||
==Scale height used in a simple atmospheric pressure model== | |||
For planetary atmospheres, '''scale height''' is the vertical distance over which the [[pressure]] of the atmosphere changes by a factor of ''e'' (decreasing upward). The scale height remains constant for a particular temperature. It can be calculated by<ref name=AMS> | |||
{{cite web | |||
|title= Glossary of Meteorology - scale height | |||
|url=http://amsglossary.allenpress.com/glossary/search?id=scale-height1 | |||
|publisher= [[American Meteorological Society]] (AMS) | |||
}}</ref><ref name=wolfram> | |||
{{cite web | |||
|title= Pressure Scale Height | |||
|url=http://scienceworld.wolfram.com/physics/PressureScaleHeight.html | |||
|publisher= [[Wolfram Research]] | |||
}}</ref> | |||
:<math>H = \frac{kT}{Mg}</math> | |||
where: | |||
* ''k'' = [[Boltzmann constant]] = 1.38 x 10<sup>−23</sup> J·K<sup>−1</sup> | |||
* ''T'' = mean atmospheric [[temperature]] in [[kelvin]]s = 250 K<ref name=Jacob1999> | |||
{{cite web | |||
|title= Daniel J. Jacob: "Introduction to Atmospheric Chemistry", Princeton University Press, 1999 | |||
|url=http://acmg.seas.harvard.edu/people/faculty/djj/book/bookchap2.html | |||
}}</ref> | |||
* ''M'' = mean [[molecular mass]] of dry air (units kg) | |||
* ''g'' = [[acceleration]] due to [[gravity]] on planetary surface (m/s²) | |||
The pressure (force per unit area) at a given altitude is a result of the weight of the overlying atmosphere. If at a height of ''z'' the atmosphere has [[density]] ''ρ'' and pressure ''P'', then moving upwards at an infinitesimally small height ''dz'' will decrease the pressure by amount ''dP'', equal to the weight of a layer of atmosphere of thickness ''dz''. | |||
Thus: | |||
:<math>\frac{dP}{dz} = -g\rho</math> | |||
where ''g'' is the acceleration due to gravity. For small ''dz'' it is possible to assume ''g'' to be constant; the minus sign indicates that as the height increases the pressure decreases. Therefore, using the [[equation of state]] for an [[ideal gas]] of mean molecular mass ''M'' at temperature ''T,'' the density can be expressed as | |||
:<math>\rho = \frac{MP}{kT}</math> | |||
Combining these equations gives | |||
:<math>\frac{dP}{P} = \frac{-dz}{\frac{kT}{Mg}}</math> | |||
which can then be incorporated with the equation for ''H'' given above to give: | |||
:<math>\frac{dP}{P} = - \frac{dz}{H}</math> | |||
which will not change unless the temperature does. Integrating the above and assuming where ''P''<sub>0</sub> is the pressure at height ''z'' = 0 (pressure at [[sea level]]) the pressure at height ''z'' can be written as: | |||
:<math>P = P_0\exp(-\frac{z}{H})</math> | |||
This translates as the pressure [[exponential decay|decreasing exponentially]] with height.<ref name=iapetus_1> | |||
{{cite web | |||
|title= Example: The scale height of the Earth's atmosphere | |||
|url=http://iapetus.phy.umist.ac.uk/Teaching/SolarSystem/WorkedExample4.pdf | |||
}}</ref> | |||
In the [[Earth's atmosphere]], the pressure at sea level ''P''<sub>0</sub> averages about 1.01×10<sup>5</sup> Pa, the mean molecular mass of dry air is 28.964 [[unified atomic mass unit|u]] and hence 28.964 × 1.660×10<sup>−27</sup> = 4.808×10<sup>−26</sup> kg, and ''[[standard gravity|g]]'' = 9.81 m/s². As a function of temperature the scale height of the Earth's atmosphere is therefore 1.38/(4.808×9.81)×10<sup>3</sup> = 29.26 m/deg. This yields the following scale heights for representative air temperatures. | |||
:''T'' = 290 K, ''H'' = 8500 m | |||
:''T'' = 273 K, ''H'' = 8000 m | |||
:''T'' = 260 K, ''H'' = 7610 m | |||
:''T'' = 210 K, ''H'' = 6000 m | |||
These figures should be compared with the temperature and density of the Earth's atmosphere plotted at [[NRLMSISE-00]], which shows the air density dropping from 1200 g/m<sup>3</sup> at sea level to 0.5<sup>3</sup> = .125 g/m<sup>3</sup> at 70 km, a factor of 9600, indicating an average scale height of 70/ln(9600) = 7.64 km, consistent with the indicated average air temperature over that range of close to 260 K. | |||
Note: | |||
* Density is related to pressure by the [[ideal gas]] laws. Therefore—with some departures caused by varying temperature—density will also decrease exponentially with height from a sea level value of ''ρ''<sub>0</sub> roughly equal to 1.2 kg m<sup>−3</sup> | |||
* At heights over 100 km, molecular [[diffusion]] means that each molecular atomic species has its own scale height. | |||
==Planetary examples== | |||
Approximate scale heights for selected Solar System bodies follow. | |||
*[[Venus]] : 15.9 km<ref>{{cite web|url=http://nssdc.gsfc.nasa.gov/planetary/factsheet/venusfact.html|title=Venus Fact Sheet|publisher=NASA|accessdate=28 September 2013}}</ref> | |||
*[[Earth]] : 8.5 km<ref>{{cite web|url=http://nssdc.gsfc.nasa.gov/planetary/factsheet/earthfact.html|title=Earth Fact Sheet|publisher=NASA|accessdate=28 September 2013}}</ref> | |||
*[[Mars]] : 11.1 km<ref>{{cite web|url=http://nssdc.gsfc.nasa.gov/planetary/factsheet/marsfact.html|title=Mars Fact Sheet|publisher=NASA|accessdate=28 September 2013}}</ref> | |||
*[[Jupiter]] : 27 km<ref>{{cite web|url=http://nssdc.gsfc.nasa.gov/planetary/factsheet/jupiterfact.html|title=Jupiter Fact Sheet|publisher=NASA|accessdate=28 September 2013}}</ref> | |||
*[[Saturn]] : 59.5 km<ref>{{cite web|url=http://nssdc.gsfc.nasa.gov/planetary/factsheet/saturnfact.html|title=Saturn Fact Sheet|publisher=NASA|accessdate=28 September 2013}}</ref> | |||
:*[[Titan (moon)|Titan]] : 40 km<ref>{{cite web|url=http://www.mrc.uidaho.edu/entryws/presentations/Papers/Justus.doc|title=Engineering-Level Model Atmospheres For Titan and Mars|last=Justus|first=C. G.|coauthors=Aleta Duvall, Vernon W. Keller|date=November 2003 and February 2004|work=International Workshop on Planetary Probe Atmospheric Entry and Descent Trajectory Analysis and Science, Lisbon, Portugal, October 6-9, 2003, Proceedings: ESA SP-544|publisher=ESA|accessdate=28 September 2013}}</ref> | |||
*[[Uranus]] : 27.7 km<ref>{{cite web|url=http://nssdc.gsfc.nasa.gov/planetary/factsheet/uranusfact.html|title=Uranus Fact Sheet|publisher=NASA|accessdate=28 September 2013}}</ref> | |||
*[[Neptune]] : 19.1 - 20.3 km<ref>{{cite web|url=http://nssdc.gsfc.nasa.gov/planetary/factsheet/neptunefact.html|title=Neptune Fact Sheet|publisher=NASA|accessdate=28 September 2013}}</ref> | |||
==See also== | |||
*[[Time constant]] | |||
==References== | |||
{{reflist|colwidth=30em}} | |||
[[Category:Atmosphere]] | |||
[[Category:Atmospheric dynamics]] |
Revision as of 17:07, 12 December 2013
In various scientific contexts, a scale height is a distance over which a quantity decreases by a factor of e (approximately 2.71828, the base of natural logarithms). It is usually denoted by the capital letter H.
Scale height used in a simple atmospheric pressure model
For planetary atmospheres, scale height is the vertical distance over which the pressure of the atmosphere changes by a factor of e (decreasing upward). The scale height remains constant for a particular temperature. It can be calculated by[1][2]
where:
- k = Boltzmann constant = 1.38 x 10−23 J·K−1
- T = mean atmospheric temperature in kelvins = 250 K[3]
- M = mean molecular mass of dry air (units kg)
- g = acceleration due to gravity on planetary surface (m/s²)
The pressure (force per unit area) at a given altitude is a result of the weight of the overlying atmosphere. If at a height of z the atmosphere has density ρ and pressure P, then moving upwards at an infinitesimally small height dz will decrease the pressure by amount dP, equal to the weight of a layer of atmosphere of thickness dz.
Thus:
where g is the acceleration due to gravity. For small dz it is possible to assume g to be constant; the minus sign indicates that as the height increases the pressure decreases. Therefore, using the equation of state for an ideal gas of mean molecular mass M at temperature T, the density can be expressed as
Combining these equations gives
which can then be incorporated with the equation for H given above to give:
which will not change unless the temperature does. Integrating the above and assuming where P0 is the pressure at height z = 0 (pressure at sea level) the pressure at height z can be written as:
This translates as the pressure decreasing exponentially with height.[4]
In the Earth's atmosphere, the pressure at sea level P0 averages about 1.01×105 Pa, the mean molecular mass of dry air is 28.964 u and hence 28.964 × 1.660×10−27 = 4.808×10−26 kg, and g = 9.81 m/s². As a function of temperature the scale height of the Earth's atmosphere is therefore 1.38/(4.808×9.81)×103 = 29.26 m/deg. This yields the following scale heights for representative air temperatures.
- T = 290 K, H = 8500 m
- T = 273 K, H = 8000 m
- T = 260 K, H = 7610 m
- T = 210 K, H = 6000 m
These figures should be compared with the temperature and density of the Earth's atmosphere plotted at NRLMSISE-00, which shows the air density dropping from 1200 g/m3 at sea level to 0.53 = .125 g/m3 at 70 km, a factor of 9600, indicating an average scale height of 70/ln(9600) = 7.64 km, consistent with the indicated average air temperature over that range of close to 260 K.
Note:
- Density is related to pressure by the ideal gas laws. Therefore—with some departures caused by varying temperature—density will also decrease exponentially with height from a sea level value of ρ0 roughly equal to 1.2 kg m−3
- At heights over 100 km, molecular diffusion means that each molecular atomic species has its own scale height.
Planetary examples
Approximate scale heights for selected Solar System bodies follow.
See also
References
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