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Metric tensor (general relativity)

 

 
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Metric tensor (general relativity)
 
 
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In general relativity
General relativity

General relativity or the general theory of relativity is the Geometry Theoretical physics of gravitation published by Albert Einstein in 1916....
, the metric tensor (or simply, the metric) is the fundamental object of study. It may loosely be thought of as a generalization of the gravitational field
Gravitational field

A gravitational field is a scientific model used within physics to explain how gravitation exists in the universe. In its original concept, gravity was a force between point masses....
 familiar from Newtonian gravitation. The metric captures all the geometric and causal structure of spacetime
Spacetime

In physics, spacetime is any mathematical model that combines space and Time in physics into a single continuum . Spacetime is usually interpreted with space being Three-dimensional space and time playing the role of a fourth dimension that is of a different sort than the spatial dimensions....
, being used to define notions such as distance, volume, curvature, angle, future and past.

Notation and conventions: Throughout this article we work with a metric signature
Metric signature

The signature of a metric tensor is the number of positive and negative eigenvalues of the metric. That is, the corresponding real symmetric matrix is diagonalisation, and the diagonal entries of each sign counted....
 that is mostly positive (-+++); see sign convention
Sign convention

In physics, a sign convention is a choice of the Negative and non-negative numberss of a set of quantities, in a case where the choice of sign is arbitrary....
.






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In general relativity
General relativity

General relativity or the general theory of relativity is the Geometry Theoretical physics of gravitation published by Albert Einstein in 1916....
, the metric tensor (or simply, the metric) is the fundamental object of study. It may loosely be thought of as a generalization of the gravitational field
Gravitational field

A gravitational field is a scientific model used within physics to explain how gravitation exists in the universe. In its original concept, gravity was a force between point masses....
 familiar from Newtonian gravitation. The metric captures all the geometric and causal structure of spacetime
Spacetime

In physics, spacetime is any mathematical model that combines space and Time in physics into a single continuum . Spacetime is usually interpreted with space being Three-dimensional space and time playing the role of a fourth dimension that is of a different sort than the spatial dimensions....
, being used to define notions such as distance, volume, curvature, angle, future and past.

Notation and conventions: Throughout this article we work with a metric signature
Metric signature

The signature of a metric tensor is the number of positive and negative eigenvalues of the metric. That is, the corresponding real symmetric matrix is diagonalisation, and the diagonal entries of each sign counted....
 that is mostly positive (-+++); see sign convention
Sign convention

In physics, a sign convention is a choice of the Negative and non-negative numberss of a set of quantities, in a case where the choice of sign is arbitrary....
. As is customary in relativity, units
Natural units

In physics, natural units are physical units of measurement defined in such a way that certain selected universal physical constants are normalized to unity; that is, their numerical value becomes exactly 1 when measured in some system of natural units....
 are used where the speed of light
Speed of light

The speed of light in an free space is an important physical constant usually written as c, with a value of 299,792,458 metres per second....
 c = 1. The gravitation constant G will be kept explicit. The summation convention, where repeated indices are automatically summed over, will be employed.


Definition


Mathematically, spacetime is represented by a 4-dimensional differentiable manifold
Differentiable manifold

A differentiable manifold is a type of manifold that is locally similar enough to Euclidean space to allow one to do calculus. This article deals with differentiability in different contexts including: smooth function, k times differentiable, and holomorphic function....
 M and the metric is given as a covariant, second-rank, symmetric tensor
Symmetric tensor

In mathematics, a symmetric tensor is a tensor that is invariant under a permutation of its vector arguments. Symmetric tensors of rank two are sometimes called quadratic forms....
 on M, conventionally denoted by g. Moreover the metric is required to be nondegenerate with signature
Metric signature

The signature of a metric tensor is the number of positive and negative eigenvalues of the metric. That is, the corresponding real symmetric matrix is diagonalisation, and the diagonal entries of each sign counted....
 (-+++). A manifold M equipped with such a metric is called a Lorentzian manifold.

Explicitly, the metric is a symmetric bilinear form
Symmetric bilinear form

A symmetric bilinear form is, as the name implies, a bilinear form on a vector space that is symmetric. They are of great importance in the study of orthogonal polarities and quadric ....
 on each tangent space
Tangent space

In mathematics, the tangent space of a manifold is a concept which facilitates the generalization of vectors from affine spaces to general manifolds, since in the latter case one cannot simply subtract two points to obtain a vector pointing from one to the other....
 of M which varies in a smooth (or differentiable) manner from point to point. Given two tangent vectors u and v and a point x in M, the metric can be evaluated on u and v to give a real number: This can be thought of as a generalization of the dot product
Dot product

In mathematics, the dot product, also known as the scalar product, is an operation which takes two vector over the real numbers R and returns a real-valued scalar quantity....
 in ordinary Euclidean space
Euclidean space

Around 300 Before Christ, the Ancient Greece mathematician Euclid undertook a study of relationships among distances and angles, first in a plane and then in space....
. This analogy is not exact, however. Unlike Euclidean space — where the dot product is positive definite
Positive definite

In mathematics, positive definite may refer to:* positive-definite matrix* positive-definite function** positive definite function on a group...
 — the metric gives each tangent space the structure of Minkowski space
Minkowski space

In physics and mathematics, Minkowski space is the mathematical setting in which Albert Einstein theory of special relativity is most conveniently formulated....
.

Local coordinates and matrix representations


Physicists usually work in local coordinates
Local coordinates

Local coordinates are measurement indices into a local coordinate system or a local coordinate space. A simple example is using house numbers to locate a house on a street; the street is a local coordinate system within a larger system composed of city townships, states, countries, etc....
 (i.e. coordinates defined on some local patch
Atlas (topology)

In mathematics, particularly topology, an atlas describes how a manifold is equipped with a differential structure. Each piece is given by a chart ....
 of M). In local coordinates (where is an index which runs from 0 to 3) the metric can be written in the form The factors are one-form
One-form

In linear algebra, a one-form on a vector space is the same as a linear functional on the space. The usage of one-form in this context usually distinguishes the one-forms from higher-degree multilinear form on the space....
 gradient
Gradient

In vector calculus, the gradient of a scalar field is a vector field which points in the direction of the greatest rate of increase of the scalar field, and whose magnitude is the greatest rate of change....
s of the scalar coordinate fields . The metric is thus a linear combination of tensor product
Tensor product

In mathematics, the tensor product, denoted by , may be applied in different contexts to vector spaces, matrix , tensors, vector spaces, algebra over a field, topological vector spaces, and module s....
s of one-form gradients of coordinates. The coefficients are a set of 16 real-valued functions (since the tensor g is actually a tensor field defined at all points of a spacetime
Spacetime

In physics, spacetime is any mathematical model that combines space and Time in physics into a single continuum . Spacetime is usually interpreted with space being Three-dimensional space and time playing the role of a fourth dimension that is of a different sort than the spatial dimensions....
 manifold). In order for the metric to be symmetric we must have giving 10 independent coefficients. If we denote the symmetric tensor product
Tensor product

In mathematics, the tensor product, denoted by , may be applied in different contexts to vector spaces, matrix , tensors, vector spaces, algebra over a field, topological vector spaces, and module s....
 by juxtaposition (so that ) we can write the metric in the form

If the local coordinates are specified, or understood from context, the metric can be written as a 4×4 symmetric matrix
Symmetric matrix

In linear algebra, a symmetric matrix is a square matrix, A, that is equal to its transposeThe entries of a symmetric matrix are symmetric with respect to the main diagonal ....
 with entries . The nondegeneracy of means that this matrix is non-singular (i.e. has non-vanishing determinant), while the Lorentzian signature of g implies that the matrix has one negative and three positive eigenvalues. Note that physicists often refer to this matrix or the coordinates themselves as the metric (see, however, abstract index notation
Abstract index notation

Abstract index notation is a mathematical notation for tensors and spinors that uses indices to indicate their types, rather than their components in a particular basis....
).

With the quantity being an infinitesimal coordinate displacement, the metric acts as an infinitesimal invariant interval squared or line element
Line element

A line element in mathematics can most generally be thought of as the square of the change in a position vector in an affine space equated to the square of the change of the arc length....
. For this reason one often sees the notation for the metric: In general relativity, the terms metric and line element are often used interchangeably.

The line element imparts information about the causal structure of the spacetime. When , the interval is timelike
Minkowski space

In physics and mathematics, Minkowski space is the mathematical setting in which Albert Einstein theory of special relativity is most conveniently formulated....
 and the square root of the absolute value of ds2 is an incremental proper time
Proper time

In theory of relativity, proper time is time measured by a single clock between events that occur at the same place as the clock. It depends not only on the events but also on the motion of the clock between the events....
. Only timelike intervals can be physically traversed by a massive object. When , the interval is lightlike, and can only be traversed by light. When , the interval is spacelike and the square root of ds2 acts as an incremental proper length
Proper length

In theory of relativity physics, proper length is an invariant quantity which is the ruler distance between spacelike-separated Spacetime#Basic conceptss in a frame of reference in which the events are simultaneous....
. Spacelike intervals cannot be traversed, since they connect events that are out of each other's light cone
Light cone

In special relativity, a light cone is the surface describing the temporal evolution of a flash of light in Minkowski spacetime. This can be visualized in 3-space if the two horizontal axes are chosen to be spatial dimensions, while the vertical axis is time....
s. Event
Spacetime

In physics, spacetime is any mathematical model that combines space and Time in physics into a single continuum . Spacetime is usually interpreted with space being Three-dimensional space and time playing the role of a fourth dimension that is of a different sort than the spatial dimensions....
s can be causally related only if they are within each other's light cones.

The metric components obviously depend on the chosen local coordinate system. Under a change of coordinates the metric components transform as

Examples


Flat spacetime


The simplest example of a Lorentzian manifold is flat spacetime which can be given as R4 with coordinates and the metric Note that these coordinates actually cover all of R4. The flat space metric (or Minkowski metric) is often denoted by the symbol ? and is the metric used in special relativity
Special relativity

Special relativity is the physical theory of measurement in inertial frames of reference proposed in 1905 by Albert Einstein in the paper "Annus Mirabilis Papers#Special relativity"....
. In the above coordinates, the matrix representation of ? is In spherical coordinates , the flat space metric takes the form where is the standard metric on the 2-sphere.

Schwarzschild metric


Besides the flat space metric the most important metric in general relativity is the Schwarzschild metric
Schwarzschild metric

In Albert Einstein theory of general relativity, the Schwarzschild solution describes the gravitational field outside a spherical, non-rotating mass such as a star, planet, or black hole....
 which can be given in one set of local coordinates by where, again, is the standard metric on the 2-sphere. Here G is the gravitation constant and M is a constant with the dimensions of mass
Mass

In physical science, mass refers to the degree of acceleration a body acquires when subject to a force: bodies with greater mass are accelerated less by the same force....
.

Volume


The metric g defines a natural volume form
Volume form

In mathematics, a volume element provides a means for integration a function with respect to volume in various coordinate systems such as spherical coordinates and cylindrical coordinates....
, which can be used to integrate over spacetimes. In local coordinates of a manifold, the volume form can be written where det g is the determinant
Determinant

In algebra, a determinant is a function depending on n that associates a scalar , det, to an n?n square matrix A. The fundamental geometric meaning of a determinant is a scale factor for measure when A is regarded as a linear transformation....
 of the matrix of components of the metric tensor for the given coordinate system.

Curvature


The metric g completely determines the curvature
Curvature

In mathematics, curvature refers to any of a number of loosely related concepts in different areas of geometry. Intuitively, curvature is the amount by which a geometric object deviates from being flat, or straight in the case of a line , but this is defined in different ways depending on the context....
 of spacetime. According to the fundamental theorem of Riemannian geometry
Fundamental theorem of Riemannian geometry

In Riemannian geometry, the fundamental theorem of Riemannian geometry states that on any Riemannian manifold there is a unique torsion metric affine connection, called the Levi-Civita connection of the given metric....
, there is a unique connection
Connection (mathematics)

In geometry, the notion of a connection makes precise the idea of transporting data along a curve or family of curves in a parallel and consistent manner....
 ? on any Lorentzian manifold that is compatible with the metric and torsion
Torsion

The term torsion may refer the following:*In geometry:** Torsion of curves** Torsion tensor in differential geometry** The closely related concepts of Reidemeister torsion and analytic torsion ...
-free. This connection is called the Levi-Civita connection
Levi-Civita connection

In Riemannian geometry, the Levi-Civita connection is the Torsion -free Riemannian connection, i.e., the torsion-free connection on the tangent bundle preserving a given Riemannian metric....
. The Christoffel symbols
Christoffel symbols

In mathematics and physics, the Christoffel symbols, named for Elwin Bruno Christoffel , are coordinate-space expressions for the Levi-Civita connection derived from the metric tensor....
 of this connection are given in terms of partial derivatives of the metric in local coordinates by the formula .

The curvature of spacetime is then given by the Riemann curvature tensor
Riemann curvature tensor

In the mathematical field of differential geometry, the Riemann curvature tensor or Riemann?Christoffel tensor is the most standard way to express curvature of Riemannian manifolds....
 which is defined in terms of the Levi-Civita connection ?. In local coordinates this tensor is given by:

The curvature is then expressible purely in terms of the metric and its derivatives.

Einstein's equations


One of the core ideas of general relativity is that the metric (and the associated geometry of spacetime) is determined by the matter
Matter

In common usage, matter is anything that has both mass and volume . A more rigorous definition is used in science: matter is what atoms and molecules are made of....
 and energy
Energy

In physics, energy is a scalar physical quantity that describes the amount of Work_ that can be performed by a force. Energy is an attribute of objects and systems that is subject to a conservation law....
 content of spacetime
Spacetime

In physics, spacetime is any mathematical model that combines space and Time in physics into a single continuum . Spacetime is usually interpreted with space being Three-dimensional space and time playing the role of a fourth dimension that is of a different sort than the spatial dimensions....
. Einstein's field equations
Einstein field equations

The Einstein field equations or Einstein's equations are a set of ten equations in Einstein's theory of general relativity in which the fundamental force of gravitation is described as a curved spacetime caused by matter and energy....
: relate the metric (and the associated curvature tensors) to the stress-energy tensor
Stress-energy tensor

The stress-energy tensor is a tensor quantity in physics that describes the density and flux of energy and momentum in spacetime, generalizing the stress of Newtonian physics....
 . This tensor
Tensor

A tensor is an object which extends the notion of Scalar , Vector , and Matrix . The term has slightly different meanings in mathematics and physics....
 equation is a complicated set of nonlinear partial differential equation
Partial differential equation

In mathematics, partial differential equations are a type of differential equation, i.e., a Relation involving an unknown Function of several independent variables and its partial derivatives with respect to those variables....
s for the metric components. Exact solutions of Einstein's field equations are very difficult to find.

See also


  • Mathematics of general relativity
    Mathematics of general relativity

    The mathematics of general relativity refers to various mathematics structures and techniques that are used in studying Albert Einstein's theory of general relativity....
  • Basic introduction to the mathematics of curved spacetime
    Basic introduction to the mathematics of curved spacetime

    An understanding of calculus and differential equations is necessary for the understanding of nonrelativistic physics. In order to understand special relativity one also needs an understanding of tensor calculus....