Geopotential height is a vertical coordinate referenced to Earth's mean sea level — an adjustment to geometric height (elevation above mean sea level) using the variation of gravity with latitude and elevation. Mean sea level (MSL is the average (mean height of the Sea, with reference to a suitable reference surface The elevation of a Geographic location is its height above a fixed reference point often the mean sea level. Gravitation is a natural Phenomenon by which objects with Mass attract one another Latitude, usually denoted symbolically by the Greek letter phi ( Φ) gives the location of a place on Earth (or other planetary body north or south of the Thus it can be considered a "gravity-adjusted height. " One usually speaks of the geopotential height of a certain pressure level, which would correspond to the geopotential height necessary to reach the given pressure.
At an elevation of h, the geopotential is defined as
where g(φ,z) is the acceleration due to gravity, φ is latitude, and z is the geometric elevation.
Thus, it is the gravitational potential energy per unit mass at that level. The geopotential height is
where g0 is the standard gravity at mean sea level.
Geophysical scientists often use geopotential height rather than geometric height, because doing so in many cases makes analytical calculations more convenient. For example, the primitive equations which weather forecast models solve are more easily expressed in terms of geopotential than geometric height. The primitive equations are a set of nonlinear differential equations that are used to approximate global atmospheric flow and are used in most atmospheric models Using the former eliminates centrifugal force and air density (which is very difficult to measure) in the equations. The density of air, ρ (Greek rho (air density is the mass per unit volume of Earth's atmosphere, and is a useful value in Aeronautics.
A plot of geopotential height for a single pressure level shows the troughs and ridges, Highs and Lows, which are typically seen on upper air charts. The geopotential thickness between pressure levels — difference of the 850 hPa and 1000 hPa geopotential heights for example — is proportional to mean virtual temperature in that layer. Geopotential height contours can be used to calculate the geostrophic wind, which is faster where the contours are more closely spaced and tangential to the geopotential height contours. The geostrophic wind is the Theoretical Wind that would result from an exact balance between the Coriolis force and the Pressure gradient force
Further reading
Hofmann-Wellenhof, B. and Moritz, H. Physical Geodesy, 2005. ISBN 3211235841
Eskinazi, S. Fluid Mechanics and Thermodynamics of our Environment, 1975. ISBN 0122425405
External links
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