Spacetime
A point in spacetime is usually referred to as an event. An example of an event may be the explosion of a star. The worldline of a particle or light beam is the path that this particle or beam takes in the spacetime, this path being a geodesic. In classical physics, geodesics are timelike or null (light-like).
| Table of contents |
|
2 Reference frames in spacetime 3 Distance in spacetime 4 General facts about spacetimes 5 Is spacetime quantized? 6 Related concepts |
Mathematics of spacetimes
For physical reasons, a spacetime is mathematically defined as a 4-dimensional, smooth, connected pseudo-Riemannian manifold together with a smooth, Lorentz metric of signature 
. About each point (event), p�
. Examples of spacetimes include Minkowski space.
Spacetime topology
The definition of a pseudo-Riemannian manifold includes the Hausdorff condition, and an important property of a Hausdorff space is that it is paracompact. This is useful in relativity.
- A compact manifold can be turned into a spacetime if and only if its Euler characteristic is 0.
- Any non-compact 4-manifold can be turned into a spacetime.
Reference frames in spacetime
A reference frame in spacetime is identified with one of these coordinate charts. Physically, any observer in a reference frame can describe the event p�
For example, two observers, one of whom is on Earth, but the other one who is on a fast rocket to Jupiter, may observe a comet crashing into Jupiter (this is the event p� (as they are using different coordinate systems). However, the two sets of coordinates are related by a non-singular coordinate transformation (on the intersection of the two charts). An important feature of relativity theory is its local nature (observers measure physical quantities in their own locality).
The local nature of the coordinate charts and the coordinate transformations between them serve to emphasise this fact. In general, global coordinate charts are seldom used in realistic physical situations.
In the comet example above, although the kinematic descriptions will, in general, be different, dynamical (physical) laws, such as momentum conservation and the first law of thermodynamics, will still hold. In fact, relativity theory requires more than this in the sense that it stipulates these laws must take the same form in all coordinate systems. This introduces the tensor formalism into relativity.
Distance in spacetime
A spacetime interval between two events is the frame-invariant quantity analogous to distance in Euclidean space. The spacetime interval s along a curve (geodesic) is defined in special relativity by:
The spacetime intervals on a manifold define a pseudo-metric called the Lorentz metric. This metric is very similar to distance in Euclidean space. However, note that whereas distances are always positive in Euclidean space, intervals may be positive, zero, or negative in space-time. Events with a spacetime interval of zero are separated by the propagation of a light signal. Events with a positive spacetime interval are in each other's future or past, and the value of the interval defines the proper time measured by an observer travelling between them. One of the simplest interesting examples of a spacetime is R4 with the spacetime interval defined above. This is known as Minkowski space, and is the usual geometric setting for special relativity. In contrast, general relativity stipulates that the underlying manifold will not be flat if gravity is present, and thus calls for the use of more general (curved) spacetimes. Thus, Minkowski space is excluded from general relativity as a valid physical arena.
Strictly speaking one can also consider events in Newtonian physics as a single spacetime. This is Galilean-Newtonian relativity, and the coordinate systems are related by Galilean transformations. However, since these preserve spatial and temporal distances independently, such a spacetime can be decomposed into spatial coordinates plus temporal coordinates, which is not possible in the general case.
General facts about spacetimes
Many spacetimes have physical interpretations which most physicists would consider bizarre or unsettling. For example, a compact spacetime has closed timelike curves, which violate our usual ideas of causality. For this reason, mathematical physicists usually consider only restricted subsets of all the possible spacetimes. One way to do this is to study "realistic" solutions of the equations of general relativity. Another way is add some additional "physically reasonable" but still fairly general geometric restrictions, and try to prove interesting things about the resulting spacetimes. The latter approach has led to some important results, most notably the Penrose-Hawking singularity theorems.
Is spacetime quantized?
In general relativity, spacetime is assumed to be 'smooth' and 'continuous' (not just in the mathematical sense). In the theory of quantum mechanics, there is an inherent 'discreteness' present in physics. In attempting to reconcile these two theories, it is sometimes postulated that spacetime should be quantized at the very smallest scales. Current theory is focused on the nature of spacetime at the Planck scale. Loop quantum gravity, string theory, and black hole thermodynamics all predict a quantized spacetime with agreement on the order of magnitude. Loop quantum gravity even makes precise predictions about the geometry of spacetime at the Planck scale.
Related concepts
- Galilean transformation
- Lorentz transformation
- Minkowski space
- Lorentz invariance
- Simultaneity
- Manifold
- Metric space
- Gravity
- Four-vector
- Space-time theories of consciousness
