Citizendia
Your Ad Here

For the video game, see Gravity Well (video game). Gravity Well is a Multi-directional shooter game developed and published by Software Engineering Inc

In physics, a gravity well is the gravitational potential field around a massive body (a particular kind of potential well). Physics (Greek Physis - φύσις in everyday terms is the Science of Matter and its motion. Potential energy can be thought of as Energy stored within a physical system A potential well is the region surrounding a Local minimum of Potential energy. Physical models of gravity wells are sometimes used to illustrate orbital mechanics. Orbital mechanics or astrodynamics is the application of Celestial mechanics to the practical problems concerning the motion of Rockets and other Spacecraft Gravity wells are frequently confused with general relativistic embedding diagrams, but the two concepts are unrelated. General relativity or the general theory of relativity is the geometric theory of Gravitation published by Albert Einstein in 1916

Contents

Details

Plots of two-dimensional and one-dimensional slices of the gravitational potential around a uniformly dense, spherically symmetric body.
Plots of two-dimensional and one-dimensional slices of the gravitational potential around a uniformly dense, spherically symmetric body.

The external gravitational potential of a spherically symmetric body of mass M is given by \Phi(\mathbf{x}) = -\frac{GM}{|\mathbf{x}|}. A plot of this function in two dimensions is shown in the figure. This plot has been completed with an interior potential proportional to |\mathbf{x}|^2, corresponding to an object of uniform density, but this interior potential is generally irrelevant since the orbit of a test particle cannot intersect the body.

The potential function has a hyperbolic cross section; the sudden dip in the center is the origin of the name "gravity well. In Geometry, a hyperbola ( Greek, "over-thrown" has several equivalent definitions "

Physical gravity wells

In a uniform gravitational field, the gravitational potential at a point is proportional to the height. Thus if the graph of a gravitational potential Φ(x,y) is constructed as a physical surface and placed in a uniform gravitational field so that the actual field points in the − Φ direction, then each point on the surface will have an actual gravitational potential proportional to the value of Φ at that point. In mathematics the graph of a function f is the collection of all Ordered pairs ( x, f ( x) As a result, an object constrained to move on the surface will have roughly the same equation of motion as an object moving in the potential field Φ itself. Gravity wells constructed on this principle can be found in many science museums.

There are several sources of inaccuracy in this model:

The rubber-sheet model

Consider an idealized rubber sheet suspended in a uniform gravitational field normal to the sheet. In equilibrium, the elastic tension in each part of the sheet must be equal and opposite to the gravitational pull on that part of the sheet; that is,

k \nabla^2 h = -g \rho

where k is the elastic constant of the rubber, h(\mathbf{x}) is the upward displacement of the sheet (assumed to be small), g is the strength of the gravitational field, and \rho(\mathbf{x}) is the mass density of the sheet. In Physics String Tension is the magnitude of the pulling force exerted by a string cable chain or similar object on another object In Mechanics, and Physics, Hooke's law of elasticity is an approximation that states that the amount by which a material body is deformed (the The mass density may be viewed as intrinsic to the sheet or as belonging to objects resting on top of the sheet. This equilibrium condition is identical in form to the gravitational Poisson equation

\nabla^2 \Phi = - 4 \pi G \rho

where \Phi(\mathbf{x}) is the gravitational potential and \rho(\mathbf{x}) is the mass density. In Mathematics, Poisson's equation is a Partial differential equation with broad utility in Electrostatics, Mechanical engineering and Theoretical Thus, to a first approximation, a massive object placed on a rubber sheet will deform the sheet into a correctly shaped gravity well, and (as in the rigid case) a second test object placed near the first will gravitate toward it in an approximation of the correct force law. More generally, a collection of objects placed on the sheet will mutually gravitate in roughly the way predicted by Newton's law of gravitation.

This model is somewhat less suited to classroom demonstration than the rigid gravity well because a physical two-dimensional rubber sheet will deform according to the two-dimensional analogue of Newtonian gravity, which has a 1/r force law. To obtain the correct 1/r² force law, one needs a three-dimensional rubber sheet bending into a fourth spatial dimension.

Gravity wells and general relativity

Both the rigid gravity well and the rubber-sheet model are frequently misidentified as models of general relativity, due to an accidental resemblance to general relativistic embedding diagrams. General relativity or the general theory of relativity is the geometric theory of Gravitation published by Albert Einstein in 1916 In particular, the embedding diagram most commonly found in textbooks (an isometric embedding of a constant-time equatorial slice of the Schwarzschild metric in Euclidean 3-space) superficially resembles a gravity well. In Mathematics, an embedding (or imbedding) is one instance of some Mathematical structure contained within another instance such as a group In Einstein's theory of General relativity, the Schwarzschild solution (or the Schwarzschild vacuum) describes the Gravitational field outside

Embedding diagrams are, however, fundamentally different from gravity wells in a number of ways. Most importantly, an embedding is merely a shape, while a potential plot has a distinguished "downward" direction; thus turning a gravity well "upside down" (by negating the potential) turns the attractive force into a repulsive force, while turning a Schwarzschild embedding upside down (by rotating it) has no effect, since it leaves its intrinsic geometry unchanged. Geodesics on the Schwarzschild surface do bend toward the central mass like a ball rolling in a gravity well, but for entirely different reasons. There is no analogue of the Schwarzschild embedding for a repulsive field: while such a field can be modeled in general relativity, the spatial geometry cannot be embedded in three dimensions.

The Schwarzschild embedding is commonly drawn with a hyperbolic cross section like the potential well, but in fact it has a parabolic cross section which, unlike the gravity well, does not approach a planar asymptote. In Mathematics, the parabola (pəˈræbələ from the Greek παραβολή) is a Conic section, the intersection of a right circular An asymptote of a real-valued function y=f(x is a curve which describes the behavior of f as either x or y goes to infinity See Flamm's paraboloid. In Einstein's theory of General relativity, the Schwarzschild solution (or the Schwarzschild vacuum) describes the Gravitational field outside

Misconceptions

Students of physics often have trouble conceiving of how the model of the gravity well is an acceleration vector field representation as opposed to an actual physical constant.

The rubber-sheet universe model both helps and hinders, in that the model posits a gravitational field pulling objects down into a rubber sheet to produce the gravity well effect. The reality is somewhat different, and educators in physics often go to great pains to explain this, although many students, even very advanced ones, struggle to shake off the paradigm of the rubber sheet.

© 2009 citizendia.org; parts available under the terms of GNU Free Documentation License, from http://en.wikipedia.org
 Dapyx Software network: MP3 Explorer | Ebook Manager | Zenithic