Geopotential

Geopotential is the potential of the Earth's gravity field. For convenience it is often defined as the negative of the potential energy per unit mass, so that the gravity vector is obtained as the gradient of the geopotential, without the negation. In addition to the actual potential (the geopotential), a hypothetical normal potential and their difference, the disturbing potential, can also be defined.

Concepts

For geophysical applications, gravity is distinguished from gravitation. Gravity is defined as the resultant force of gravitation and the centrifugal force caused by the Earth's rotation. Likewise, the respective scalar potentials can be added to form an effective potential called the geopotential, $W$ . The surfaces of constant geopotential or isosurfaces of the geopotential are called equigeopotential surfaces (sometimes abbreviated as geop),^[1] also known as geopotential level surfaces, equipotential surfaces, or simply level surfaces.^[2]

Global mean sea surface is close to one equigeopotential called the geoid.^[3] How the gravitational force and the centrifugal force add up to a force orthogonal to the geoid is illustrated in the figure (not to scale). At latitude 50 deg the off-set between the gravitational force (red line in the figure) and the local vertical (green line in the figure) is in fact 0.098 deg. For a mass point (atmosphere) in motion the centrifugal force no more matches the gravitational and the vector sum is not exactly orthogonal to the Earth surface. This is the cause of the coriolis effect for atmospheric motion.

The geoid is a gently undulating surface due to the irregular mass distribution inside the Earth; it may be approximated however by an ellipsoid of revolution called the reference ellipsoid. The currently most widely used reference ellipsoid, that of the Geodetic Reference System 1980 (GRS80), approximates the geoid to within a little over ±100 m. One can construct a simple model geopotential $U$ that has as one of its equipotential surfaces this reference ellipsoid, with the same model potential $U_{0}$ as the true potential $W_{0}$ of the geoid; this model is called a normal potential. The difference $T=W-U$ is called the disturbing potential. Many observable quantities of the gravity field, such as gravity anomalies and deflections of the vertical (plumb-line), can be expressed in this disturbing potential.

Background

Diagram of two masses attracting one another

Newton's law of universal gravitation states that the gravitational force F acting between two point masses m₁ and m₂ with centre of mass separation r is given by

\mathbf {F} =-G{\frac {m_{1}m_{2}}{r^{2}}}\mathbf {\hat {r}}

where G is the gravitational constant and r̂ is the radial unit vector. For a non-pointlike object of continuous mass distribution, each mass element dm can be treated as mass distributed over a small volume, so the volume integral over the extent of object 2 gives:

\mathbf {\bar {F}} =-Gm_{1}\int \limits _{V}{\frac {\rho _{2}}{r^{2}}}\mathbf {\hat {r}} \,dx\,dy\,dz

(1)

with corresponding gravitational potential

V=-G\int \limits _{V}{\frac {\rho _{2}}{r}}\,dx\,dy\,dz

(2)

where ρ₂ = ρ(x, y, z) is the mass density at the volume element and of the direction from the volume element to point mass 1. $u$ is the gravitational potential energy per unit mass.

Earth's gravity field can be derived from a gravity potential (geopotential) field as follows:

\mathbf {g} =\nabla W=\mathrm {grad} \ W={\frac {\partial W}{\partial X}}\mathbf {i} +{\frac {\partial W}{\partial Y}}\mathbf {j} +{\frac {\partial W}{\partial Z}}\mathbf {k}

which expresses the gravity acceleration vector as the gradient of $W$ , the potential of gravity. The vector triad $\{\mathbf {i} ,\mathbf {j} ,\mathbf {k} \}$ is the orthonormal set of base vectors in space, pointing along the $X,Y,Z$ coordinate axes. Here, $X$ , $Y$ and $Z$ are geocentric coordinates.

Formulation

Both gravity and its potential contain a contribution from the centrifugal pseudo-force due to the Earth's rotation. We can write

W=V+\Phi \,

where $V$ is the potential of the gravitational field, $W$ that of the gravity field, and $\Phi$ that of the centrifugal field.

Centrifugal potential

The centrifugal force—per unit of mass, i.e., acceleration—is given by

\mathbf {g} _{c}=\omega ^{2}\mathbf {p} ,

where

\mathbf {p} =X\mathbf {i} +Y\mathbf {j} +0\cdot \mathbf {k}

is the vector pointing to the point considered straight from the Earth's rotational axis. It can be shown that this pseudo-force field, in a reference frame co-rotating with the Earth, has a potential associated with it in terms of Earth's rotation rate, ω:

\Phi ={\frac {1}{2}}\omega ^{2}(X^{2}+Y^{2}).

This can be verified by taking the gradient ( $\nabla$ ) operator of this expression.

The centrifugal potential can also be expressed in terms of spherical latitude φ and geocentric radius r:

\Phi =0.5\,\omega ^{2}r^{2}\sin ^{2}\phi

Normal potential

The Earth is approximately an ellipsoid. So, it is accurate to approximate the geopotential by a field that has the Earth reference ellipsoid as one of its equipotential surfaces.

Like the actual geopotential field W, the normal field U (not to be confused with the potential energy, also U) is constructed as a two-part sum:

U=\Psi +\Phi

where $\Psi$ is the normal gravitational potential and $\Phi$ is the centrifugal potential.

A closed-form exact expression exists in terms of ellipsoidal-harmonic coordinates (not to be confused with geodetic coordinates).^[4] It can also be expressed as a series expansion in terms of spherical coordinates; truncating the series results in:^[4]

\Psi \approx (GM/r)(1-(a/r)^{2}J_{2}((3/2)\cos ^{2}(\phi )-1/2))

where a is semi-major axis and J₂ is the second dynamic form factor.^[4]

The most recent Earth reference ellipsoid is GRS80, or Geodetic Reference System 1980, which the Global Positioning system uses as its reference. Its geometric parameters are: semi-major axis a = 6378137.0 m, and flattening f = 1/298.257222101. If we also require that the enclosed mass is equal to the known mass of the Earth (including atmosphere) GM = 3986005 × 10⁸ m³·s⁻², we obtain for the potential at the reference ellipsoid:

U_{0}=62636860.850\ {\textrm {m}}^{2}\,{\textrm {s}}^{-2}

Obviously, this value depends on the assumption that the potential goes asymptotically to zero at infinity ( $R\rightarrow \infty$ ), as is common in physics. For practical purposes it makes more sense to choose the zero point of normal gravity to be that of the reference ellipsoid, and refer the potentials of other points to this.

Disturbing potential

Once a clean, smooth geopotential field $U$ has been constructed matching the known GRS80 reference ellipsoid with an equipotential surface (we call such a field a normal potential) we can subtract it from the true (measured) potential $W$ of the real Earth. The result is defined as T, the disturbing potential:

T=W-U

The disturbing potential T is numerically a great deal smaller than U or W, and captures the detailed, complex variations of the true gravity field of the actually existing Earth from point-to-point, as distinguished from the overall global trend captured by the smooth mathematical ellipsoid of the normal potential.

Geopotential number

In practical terrestrial work, e.g., levelling, an alternative version of the geopotential is used called geopotential number $C$ , which are reckoned from the geoid upward: $C=-\left(W-W_{0}\right),$ where $W_{0}$ is the geopotential of the geoid.

Simple case: nonrotating symmetric sphere

In the special case of a sphere with a spherically symmetric mass density then ρ = ρ(s); i.e., density depends only on the radial distance

s={\sqrt {x^{2}+y^{2}+z^{2}}}\,.

These integrals can be evaluated analytically. This is the shell theorem saying that in this case:

{\bar {F}}=-{\frac {GMm}{R^{2}}}\ {\hat {r}}

(3)

with corresponding potential

\Psi =-{\frac {GM}{r}}

(4)

where M = ∫_Vρ(s)dxdydz is the total mass of the sphere.

For the purpose of satellite orbital mechanics, the geopotential is typically described by a series expansion into spherical harmonics (spectral representation). In this context the geopotential is taken as the potential of the gravitational field of the Earth, that is, leaving out the centrifugal potential. Solving for geopotential in the simple case of a nonrotating sphere, in units of [m²/s²] or [J/kg]:^[5] $\Psi (h)=\int _{0}^{h}g\,dz$ $\Psi =\int _{0}^{z}\left[{\frac {Gm}{(a+z)^{2}}}\right]dz$

Integrate to get $\Psi =Gm\left[{\frac {1}{a}}-{\frac {1}{a+z}}\right]$ where:

$G = 6.673 \times 10 -11 Nm 2 /kg 2$ is the gravitational constant,
$m = 5.975 \times 1024 kg$ is the mass of the earth,
$a = 6.378 \times 106 m$ is the average radius of the earth,
$z$ is the geometric height in meters

References

^ Hooijberg, M. (2007). Geometrical Geodesy: Using Information and Computer Technology. Springer Berlin Heidelberg. p. 9. ISBN 978-3-540-68225-7. Retrieved 2023-09-11.
^ "Geopotential". ametsoc.com. Retrieved 14 April 2023.
^ Heiskanen, Weikko Aleksanteri; Moritz, Helmut (1967). Physical Geodesy. W.H. Freeman. ISBN 0-7167-0233-9.
^ ^a ^b ^c Torge, Geodesy. 3rd ed. 2001.
^ Holton, James R. (2004). An Introduction to Dynamic Meteorology (4th ed.). Burlington: Elsevier. ISBN 0-12-354015-1.

[Hooijberg_2007_p._9-1] Hooijberg, M. (2007). Geometrical Geodesy: Using Information and Computer Technology. Springer Berlin Heidelberg. p. 9. ISBN 978-3-540-68225-7. Retrieved 2023-09-11.

[2] "Geopotential". ametsoc.com. Retrieved 14 April 2023.

[3] Heiskanen, Weikko Aleksanteri; Moritz, Helmut (1967). Physical Geodesy. W.H. Freeman. ISBN 0-7167-0233-9.

[Torge-4] Torge, Geodesy. 3rd ed. 2001.

[5] Holton, James R. (2004). An Introduction to Dynamic Meteorology (4th ed.). Burlington: Elsevier. ISBN 0-12-354015-1.

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