General relativity can be understood by examining its similarities with and departures from classical physics. The first step is the realization that classical mechanics and Newton's law of gravity admit a geometric description. The combination of this description with the laws of special relativity results in a
heuristic derivation of general relativity.
Geometry of Newtonian gravity At the base of
classical mechanics is the notion that a
body's motion can be described as a combination of free (or
inertial) motion, and deviations from this free motion. Such deviations are caused by external forces acting on a body in accordance with Newton's second
law of motion, which states that the net
force acting on a body is equal to that body's (inertial)
mass multiplied by its
acceleration. The preferred inertial motions are related to the geometry of space and time: in the standard
reference frames of classical mechanics, objects in free motion move along straight lines at constant speed. In modern parlance, their paths are
geodesics, straight
world lines in
curved spacetime. Conversely, one might expect that inertial motions, once identified by observing the actual motions of bodies and making allowances for the external forces (such as
electromagnetism or
friction), can be used to define the geometry of space, as well as a time
coordinate. However, there is an ambiguity once gravity comes into play. According to Newton's law of gravity, and independently verified by experiments such as that of
Eötvös and its successors (see
Eötvös experiment), there is a universality of free fall (also known as the weak
equivalence principle, or the universal equality of inertial and passive-gravitational mass): the trajectory of a
test body in free fall depends only on its position and initial speed, but not on any of its material properties. A simplified version of this is embodied in '''Einstein's elevator experiment''', illustrated in the figure on the right: for an observer in an enclosed room, it is impossible to decide, by mapping the trajectory of bodies such as a dropped ball, whether the room is stationary in a gravitational field and the ball accelerating, or in free space aboard a rocket that is accelerating at a rate equal to that of the gravitational field versus the ball which upon release has nil acceleration. Given the universality of free fall, there is no observable distinction between inertial motion and motion under the influence of the gravitational force. This suggests the definition of a new class of inertial motion, namely that of objects in free fall under the influence of gravity. This new class of preferred motions, too, defines a geometry of space and time—in mathematical terms, it is the geodesic motion associated with a specific
connection which depends on the
gradient of the
gravitational potential. Space, in this construction, still has the ordinary
Euclidean geometry. However, space
time as a whole is more complicated. As can be shown using simple thought experiments following the free-fall trajectories of different test particles, the result of transporting spacetime vectors that can denote a particle's velocity (time-like vectors) will vary with the particle's trajectory; mathematically speaking, the Newtonian connection is not
integrable. From this, one can deduce that spacetime is curved. The resulting
Newton–Cartan theory is a geometric formulation of Newtonian gravity using only
covariant concepts, i.e. a description which is valid in any desired coordinate system. In this geometric description,
tidal effects—the relative acceleration of bodies in free fall—are related to the derivative of the connection, showing how the modified geometry is caused by the presence of mass.
Relativistic generalization of event A As intriguing as geometric Newtonian gravity may be, its basis, classical mechanics, is merely a
limiting case of (special) relativistic mechanics. In the language of
symmetry: where gravity can be neglected, physics is
Lorentz invariant as in special relativity rather than
Galilei invariant as in classical mechanics. (The defining symmetry of special relativity is the
Poincaré group, which includes translations, rotations, boosts and reflections.) The differences between the two become significant when dealing with speeds approaching the
speed of light, and with high-energy phenomena. With Lorentz symmetry, additional structures come into play. They are defined by the set of light cones (see image). The light-cones define a causal structure: for each
event , there is a set of events that can, in principle, either influence or be influenced by via signals or interactions that do not need to travel faster than light (such as event in the image), and a set of events for which such an influence is impossible (such as event in the image). These sets are
observer-independent. In conjunction with the world-lines of freely falling particles, the light-cones can be used to reconstruct the spacetime's semi-Riemannian metric, at least up to a positive scalar factor. In mathematical terms, this defines a
conformal structure or conformal geometry. Special relativity is defined in the absence of gravity. For practical applications, it is a suitable model whenever gravity can be neglected. Bringing gravity into play, and assuming the universality of free fall motion, an analogous reasoning as in the previous section applies: there are no global
inertial frames. Instead there are approximate inertial frames moving alongside freely falling particles. Translated into the language of spacetime: the straight
time-like lines that define a gravity-free inertial frame are deformed to lines that are curved relative to each other, suggesting that the inclusion of gravity necessitates a change in spacetime geometry. A priori, it is not clear whether the new local frames in free fall coincide with the reference frames in which the laws of special relativity hold—that theory is based on the propagation of light, and thus on electromagnetism, which could have a different set of
preferred frames. But using different assumptions about the special-relativistic frames (such as their being earth-fixed, or in free fall), one can derive different predictions for the gravitational redshift, that is, the way in which the frequency of light shifts as the light propagates through a gravitational field (cf.
below). The actual measurements show that free-falling frames are the ones in which light propagates as it does in special relativity. The generalization of this statement, namely that the laws of special relativity hold to good approximation in freely falling (and non-rotating) reference frames, is known as the
Einstein equivalence principle, a crucial guiding principle for generalizing special-relativistic physics to include gravity. The same experimental data shows that time as measured by clocks in a gravitational field—
proper time, to give the technical term—does not follow the rules of special relativity. In the language of spacetime geometry, it is not measured by the
Minkowski metric. As in the Newtonian case, this is suggestive of a more general geometry. At small scales, all reference frames that are in free fall are equivalent, and approximately Minkowskian. Consequently, we are dealing with a curved generalization of Minkowski space. The
metric tensor that defines the geometry—in particular, how lengths and angles are measured—is not the Minkowski metric of special relativity, it is a generalization known as a semi- or
pseudo-Riemannian metric. Furthermore, each Riemannian metric is naturally associated with one particular kind of connection, the
Levi-Civita connection, and this is, in fact, the connection that satisfies the equivalence principle and makes space locally Minkowskian (that is, in suitable
locally inertial coordinates, the metric is Minkowskian, and its first partial derivatives and the connection coefficients vanish).
Einstein's equations Having formulated the relativistic, geometric version of the effects of gravity, the question of gravity's source remains. In Newtonian gravity, the source is mass. In special relativity, mass turns out to be part of a more general quantity called the
stress–energy tensor, which includes both
energy and momentum
densities as well as
stress:
pressure and shear. Using the equivalence principle, this tensor is readily generalized to curved spacetime. Drawing further upon the analogy with geometric Newtonian gravity, it is natural to assume that the
field equation for gravity relates this tensor and the
Ricci tensor, which describes a particular class of tidal effects: the change in volume for a small cloud of test particles that are initially at rest, and then fall freely. In special relativity,
conservation of energy–momentum corresponds to the statement that the stress–energy tensor is
divergence-free. This formula, too, is readily generalized to curved spacetime by replacing partial derivatives with their curved-
manifold counterparts,
covariant derivatives studied in differential geometry. With this additional condition—the covariant divergence of the stress–energy tensor, and hence of whatever is on the other side of the equation, is zero—the simplest nontrivial set of equations are what are called Einstein's (field) equations: {{Equation box 1 On the left-hand side is the
Einstein tensor, G_{\mu\nu}, which is symmetric and a specific divergence-free combination of the Ricci tensor R_{\mu\nu} and the metric. In particular, R=g^{\mu\nu}R_{\mu\nu} is the curvature scalar. The Ricci tensor itself is related to the more general
Riemann curvature tensor as R_{\mu\nu}={R^\alpha}_{\mu\alpha\nu}. On the right-hand side, \kappa is a constant and T_{\mu\nu} is the stress–energy tensor. All tensors are written in
abstract index notation. Matching the theory's prediction to observational results for
planetary
orbits or, equivalently, assuring that the weak-gravity, low-speed limit is Newtonian mechanics, the proportionality constant \kappa is found to be \kappa={8\pi G}/{c^4}, where G is the
Newtonian constant of gravitation and c the speed of light in vacuum. When there is no matter present, so that the stress–energy tensor vanishes, the results are the vacuum Einstein equations, R_{\mu\nu}=0. In general relativity, the
world line of a particle free from all external, non-gravitational force is a particular type of geodesic in curved spacetime. In other words, a freely moving or falling particle always moves along a geodesic. The
geodesic equation is: {d^2 x^\mu \over ds^2}+\Gamma^\mu {}_{\alpha \beta}{d x^\alpha \over ds}{d x^\beta \over ds}=0, where s is a scalar parameter of motion (e.g. the
proper time), and \Gamma^\mu {}_{\alpha \beta} are
Christoffel symbols (sometimes called the
affine connection coefficients or
Levi-Civita connection coefficients) which is symmetric in the two lower indices. Greek indices may take the values: 0, 1, 2, 3 and the
summation convention is used for repeated indices \alpha and \beta. The quantity on the left-hand-side of this equation is the acceleration of a particle, and so this equation is analogous to
Newton's laws of motion which likewise provide formulae for the acceleration of a particle. This equation of motion employs the
Einstein notation, meaning that repeated indices are summed (i.e. from zero to three). The Christoffel symbols are functions of the four spacetime coordinates, and so are independent of the velocity or acceleration or other characteristics of a
test particle whose motion is described by the geodesic equation.
Total force in general relativity In general relativity, the effective
gravitational potential energy of an object of mass
m revolving around a massive central body
M is given by U_f(r) =-\frac{GMm}{r}+\frac{L^{2}}{2mr^{2}}-\frac{GML^{2}}{mc^{2}r^{3}} A conservative total
force can then be obtained as its
negative gradient F_f(r)=-\frac{GMm}{r^{2}}+\frac{L^{2}}{mr^{3}}-\frac{3GML^{2}}{mc^{2}r^{4}} where
L is the
angular momentum. The first term represents the
force of Newtonian gravity, which is described by the inverse-square law. The second term represents the
centrifugal force in the circular motion. The third term represents the relativistic effect.
Alternatives to general relativity There are
alternatives to general relativity built upon the same premises, which include additional rules and/or constraints, leading to different field equations. Examples are
Whitehead's theory,
Brans–Dicke theory,
teleparallelism,
f(R) gravity and
Einstein–Cartan theory. == Definition and basic applications ==