More than 350 keywords from relativity and related topics, from "absolute zero" to "X-rays" - please use the menu on the left to choose a letter.
- Schwarzschild black hole
More precisely, the Schwarzschild solution is a whole family of solutions: Schwarzschild's formulae contain a free parameter m corresponding to the mass of the black hole. To each concrete value of m corresponds one specific solution to Einstein's equations, a space-time containing a spherically symmetric black hole of mass m.
The Schwarzschild solution is of practical importance as the outlying regions of the corresponding model universe describe the space-time distortion around all kinds of objects that are spherically symmetric, or nearly so, such as the sun or the earth (cf. Birkhoff's theorem).
- Schwarzschild radius
A measure for the size of a spherically symmetric black hole. It is defined using the area of the black hole's horizon: In usual high school geometry (the geometry of flat space), radius and area of a spherical surface are related as
area = 4 times pi times (radius)2.The Schwarzschild radius is defined indirectly by the formula
Area of the black hole's horizon = 4 times pi times (Schwarzschild radius)2.
There is a quite general result that says: If a sphere of matter is compressed further and further, a black hole forms as soon as the sphere's radius gets smaller than the Schwarzschild radius corresponding to the matter's mass.
- Schwarzschild solution
- See Schwarzschild black hole, Schwarzschild solution.
In the International System of units: the basic unit of time. Defined as a certain multiple of the oscillation period of electromagnetic radiation set free in a certain transition within the electron shell of atoms of the type Cesium-133.
- second of arc
- See arcminute, arcseond.
- Shapiro delay
Also: gravitational time delay. In general relativity, not only are light rays deflected, in addition gravity can lead to light taking more time in its travels through space than in classical physics. This is called Shapiro effect of Shapiro delay. It has been measured numerous times for light signals in the solar system, for instance for radar waves sent from Earth to Venus and reflected back. These radar signals took measurably longer when their path led them closely by the massive sun.
Measuring this time delay is sometimes referred to as the "fourth test of general relativity", in addition to the three classical tests of that theory.
Generically, an extended body in free fall will experience deformation due to tidal effects. For instance, in a body falling towards Earth, those parts that are slightly closer to the Earth will experience a slightly stronger gravitational pull than parts which are further away. Some of the deformation will change the body's volume. The shear is that part of the deformation which does not change the volume, only the body's shape.
Some examples for shear can be found in the spotlight text Of singularities and breadmaking.
The international system of physical units, introduced in 1960. It is based on seven fundamental units; in the context of Einstein Online, the interesting ones are the meter as a measure of length and distance, the second as the unit of time, the kilogram as the unit of mass and the Kelvin as the unit of temperature.
By multiplication and division, the seven fundamental units can be used to construct derived units for all other physical quantities. For instance, the unit of speed is the distance unit divided by the unit of time, meter per second.
The sine, written sin(x), is a mathematical function that is perfectly regular and repetitive, with maximal and minimal values following each other in endless procession. The function is plotted here:
Sine waves are the simplest waves imaginable, with crests and valleys following each other in exactly the way described by a sine function.
Irregular boundary of space-time in general relativity - region where space-time simply comes to an end. Often, such boundaries are associated with space-time curvature growing beyond all bounds and becoming infinitely large - so-called curvature singularities (notably Ricci singularities or Weyl singularities) - but there are exceptions (for instance a conic singularities).
According to general relativity, there exists a singularity inside every black hole, and the starting point of any universe described by a big bang model is a singularity, as well. The occurence of sinularities is a failure of general relativity - and a strong indication that the theory is incomplete. Instead, one such describe the earliest universe and the interior of black holes using a theory of quantum gravity.
- singularity theorems
Theorems, proved by Roger Penrose and Stephen Hawking, that state under which circumstances singularities are inevitable in general relativity. As the theorems assume the laws of general relativity and certain general properties of matter, but nothing else, they are valid quite generally. In particular, these theorems prove that, in the frame-work of general relativity, every black hole must contain a singularity, and every expanding universe like ours must have begun in a big bang singularity.
- solar mass
The sun has a mass of 1.989·1030 kilograms.
[Problems reading expressions such as 1030? See exponential notation.]
In astronomy, the solar mass is frequently used as a unit of mass ("Neutron stars typically have a mass of 1.4 solar masses").
- solar system
In the context of relativity, the solar system is interesting as a natural laboratory in which the prediction of general relativity can be tested - in particular those that differ from the predictions of classical, Newtonian gravity. Examples are the relativistic perihelion shift of planetary orbits, the deflection of light close to the sun and the Shapiro effect.
- solid state
State of matter in which the atoms or molecules are bound so tightly to each other so that they form a solid, stable lump. In contrast with fluids, whose form adapts to whatever container they are placed in, solid bodies keep their form.
- In the context of general relativity: a solution or, more precisely, a solution of the Einstein equations is a model universe that follows the law of gravity as prescribed by general relativity.
In a strict sense: Space as we know it from everyday life: the totality of all locations in which objects can sit, with three dimensions.
In a more general sense used by mathematicians, all kinds of sets of points are spaces - a line for instance, which has but a single dimension, or a two-dimensional surface, but also higher-dimensional spaces. Also, in such more general spaces, geometry can be different from the standard Euclidean geometry taught in high schools - such spaces can be curved.
- Space Telescope Science Institute
The institute operating the Hubble space telescope; located in Baltimore, USA.
Already in special relativity, observer in motion relative each other will not, in general, agree as to whether two events happen simultaneously, or as to how great is the distance between two objects. They do, however, agree as to what events there are, although not to when and where they happen. This observer-independent totality of all events is called space-time. How space-time is split into space and time can differ from observer to observer.
Every-day space has three dimensions. Adding time adds another dimension - space-time has four dimensions, all in all.
We are used to the notion of a point in space - an object with but a single location, defined completely once its space coordinates are given. In spacetime, a spacetime point is an object defined completely once its space coordinates and its time coordinate are given - which makes a space-time point nothing but an elementary event.
The idea of space-time is, in addition to its role in special relativity, a building block of general relativity. Analogous to how a plane is flat, but the surface of a sphere is curved, in general relativity, curved or distorted versions of the simple, flat space-time of special relativity play a role. Space-time curvature, in general relativity, is intimately connected with gravity.
For an introduction to the basics of both theories of relativity, check out the chapters Special relativity and General relativity in Elementary Einstein. Sometimes, it can be helpful to view space-time in analogy to ordinary space - such analogies are explored in the spotlight topics Time dilation on the road (for time dilation) and Twins on the road (for the twin effect).
- space-time singularity
See entry singularity, space-time singularity above.
- special relativity
The electromagnetic radiation reaching us from an astronomical object or other source is a mix of electromagnetic waves with a great variety of frequencies. The spectrum lists the composition of this mix: For every frequency, it states the amount of radiation energy contributed by waves of that particular frequency.
An object's average speed is the distance it moves during a given period of time, divided by the length of the time interval. If you make the time interval infinitely small, the result is the object's speed at one particular moment in time. The notion of speed can be applied to waves in different ways; for instance, for a simple wave, the phase speed is the speed at which any given wave crest or wave through propagates through space.
Cf. the more general entry velocity.
- speed of light
The speed at which light or, more generally, electromagnetic radiation propagates through space (especially: through empty space). Central quantity in special relativity: There, the constancy of the speed of light is a basic postulate: ever observer (more precisely: every inertial observer) that measures the speed of light in a vacuum obtains the same constant value, c=299,792,458 metres per second.
Another important relativistic aspect of the speed of light is that it defines an absolute upper speed limit: In special relativity, nothing can move faster than light, and information or influence at most be transmitted at light-speed. In general relativity, the same law is in force locally: No object, no matter, no information can directly overtake or catch up with light (cf. causality).
A spherical surface is a simple example for a curved surface. It is easily pictured as a surface embedded in three-dimensional space: in space, a spherical surface is the set of all points at a certain fixed distance from a given point (the point being the centre of the sphere). Mathematically, a spherical surface can be described without recourse to three-dimensional space - when mathematicians talk of the geometry of such a surface, they (almost) always mean the "inner geometry": Those properties of the surface noticeable to two-dimensional beings, living and working in that surface, capable of measuring distances and angles in it.
Sphere is regularly used as a synonym for spherical surface (instead of describing a solid, three-dimensional ball). And not only for the two-dimensional spherical surface described above, but also for its analogues in lower and higher dimensions. A one-sphere, for instance, is the same as a circle, a two-sphere is the spherical surface defined above, a three-sphere its three-dimensional analogue.
Fundamental quantum property of elementary as well as of compound particles. For elementary particles, the spin determines whether the particle is a matter particle (half-integer spin such as 1/2, 3/2, 5/2 etc.) or a force particle (integer spin such as 0, 1, 2 etc.).
- spin network
In loop quantum gravity (one of the candidates for a theory of quantum gravity), the underlying microscopic structure of space is a spin network - a graph consisting of lines and nodes where each line is assigned a label consisting of a half-integer number. Mathematically, that number is closely connected with the spin of elementary particles.
More information about spin networks can be found in the spotlight topic The fabric of space: spin networks.
- standard acceleration
The acceleration imparted by the earth's gravitation to a body located on the earth's surface: If you raise such a body up a bit and let it fall, it will accelerate 9.81 meters per second2 (32.17 feet per second2), in other words: in every second, its speed will increase by 9.81 meters per second (32.17 feet per second).
Standard acceleration, abbreviated as g, is often used as a measure for accelerations. For instance, an acceleration of 2 g corresponds to 2·9.81=19.62 meters per second2.
- standard model of cosmology
- Another name for the big bang models.
- standard model of elementary particle physics
The current state of the art for describing the basic properties of matter and forces. The standard model theories are based on special relativity and quantum theory and they describe the behaviour of elementary matter particles such as electrons, neutrinos and quarks as well as their anti-particles. It also describes three quantum forces acting between them: electromagnetism, the weak nuclear force and the strong nuclear force. These forces act by the exchange of force particles. There is one elementary force for which no such quantum description exists, and which is not part of the standard model: gravity.
A cosmic gas ball that is massive enough for pressure and temperatur in its core to reach values where self-sustained nuclear fusion reactions set in. The energy set free in these reactions makes stars into very bright sources of light and other forms of electromagnetic radiation.