- Gravity anomaly
A gravity anomaly is the difference between the observed
gravity and a value predicted from a model.Geodesy and geophysics
In
geodesy andgeophysics , the usual model is the surface of a global spheroid (ellipsoid of Hayford orWGS84 ) by rather simple formulae (2 functions oflatitude ).The observed value of gravity has to be reduced down to the zero level of the
geoid , using
# theelevation of the point wheregravimetry was done
# the normalgradient of gravity (rate of change of gravity for change of elevation), as in free air, usually 0.3086milligal s per meter, or the "Bouguer gradient" of 0.1967 mGal/m (19.67 µm/(s²·m) which considers the mean rock density (2.67 g/cm³) beneath the point; this value is found by subtracting the gravity due to theBouguer plate , which is 0.1119 mGal/m (11.19 µm/(s²·m)) for this density.
# and (in special cases) aterrain model, using amap or a digital terrain model (DTM).For these reductions, different methods are used:
*
free-air anomaly (orFaye 'sanomaly ): application of the "normal gradient" 0.3086, but no terrain model. This anomaly means a downward shift of the point, together with the whole shape of the terrain. This simple method is ideal for many geodetic applications.
* simpleBouguer anomaly : downward reduction just by the Bouguer gradient (0.1967). This anomaly handles the point as if it is located on a flat plain.
* refined (or complete)Bouguer anomaly (usual abbreviation Δ"g"B): the DTM is considered as accurate as possible, using a standarddensity of 2.67 g/cm³ (granite , limestone). Bouguer anomalies are ideal forgeophysics because they show the effects of different rock densities in the subsurface.
** The difference between the two - the differential gravitational effect of the unevenness of the terrain - is called theterrain effect . It is always negative (up to 100 milligals).
** The difference between "Faye anomaly" and Δ"g"B is called "Bouguer reduction" (attraction of the terrain).
* special methods like that of Poincare-Prey , using an interior gravitygradient of about 0.009 milligal per meter (90 nm/(s²·m)). These methods are valid for the gravity withinborehole s or for specialgeoid computations.The Bouguer anomalies usually are negative in the
mountain s because ofisostasy : the rock density of theirroot s is lower, compared with the surroundingearth's mantle . Typical anomalies in theCentral alps are −150 milligals (−1.5 mm/s²). Rather local anomalies are used inapplied geophysics : if they are positive, this may indicatemetallic ore s. At scales between entire mountain ranges and ore bodies, Bouguer anomalies may indicate rock types. For example, the northeast-southwest trending high across central New Jersey (see figure) represents agraben ofTriassic age largely filled with densebasalt s.Salt dome s are typically expressed in gravity maps as lows, becausesalt has a low density compared to the rocks the dome intrudes.Astronomy
Any region of space with higher than expected mass density will produce a gravity anomaly. Observations of gravity anomalies on galactic and intergalactic scales, lead to the assumption of
dark matter .See also
* For a very different concept in physics, see
gravitational anomaly .
*Physical geodesy
*gravity
*vertical deflection External links
* [http://seis.natsci.csulb.edu/grannell/secondgravity.html Bouguer anomaly theory]
* [http://www.astro.oma.be/D1/GRAVIMETRY/gravboug.html Bouguer anomalies of Belgium. The blue regions are related to deficit masses in the subsurface - e.g. lower rock density beneath the mountains]
* [http://www.cosmology-unified.net/Gravity.Anomalies.htm The Floating Gravity]
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