Six-dimensional space

From Wikipedia, the free encyclopedia

Six-dimensional space is any space that has six dimensions, that is, six degrees of freedom, and that needs six pieces of data, or coordinates, to specify a location in this space. There are an infinite number of these, but those of most interest are simpler ones that model some aspect of the environment. Of particular interest is six-dimensional Euclidean space, in which 6-polytopes and the 5-sphere are constructed. Six-dimensional elliptical space and hyperbolic spaces are also studied, with constant positive and negative curvature.

Formally, six-dimensional Euclidean space, ℝ6, is generated by considering all real 6-tuples as 6-vectors in this space. As such it has the properties of all Euclidean spaces, so it is linear, has a metric and a full set of vector operations. In particular the dot product between two 6-vectors is readily defined, and can be used to calculate the metric. 6 × 6 matrices can be used to describe transformations such as rotations that keep the origin fixed.

More generally, any space that can be described locally with six coordinates, not necessarily Euclidean ones, is six-dimensional. One example is the surface of the 6-sphere, S6. This is the set of all points in seven-dimensional Euclidean space ℝ7 that are equidistant from the origin. This constraint reduces the number of coordinates needed to describe a point on the 6-sphere by one, so it has six dimensions. Such non-Euclidean spaces are far more common than Euclidean spaces, and in six dimensions they have far more applications.

Geometry

6-polytope

A polytope in six dimensions is called a 6-polytope. The most studied are the regular polytopes, of which there are only three in six dimensions: the 6-simplex, 6-cube, and 6-orthoplex. A wider family are the uniform 6-polytopes, constructed from fundamental symmetry domains of reflection, each domain defined by a Coxeter group. Each uniform polytope is defined by a ringed Coxeter-Dynkin diagram. The 6-demicube is a unique polytope from the D6 family, and 221 and 122 polytopes from the E6 family.

Uniform polytopes in six dimensions
(Displayed as orthogonal projections in each Coxeter plane of symmetry)
A6 BC6 D6 E6

6-simplex

6-cube

6-orthoplex

6-demicube

221

122

5-sphere

The 5-sphere, or hypersphere in six dimensions, is the five dimensional surface equidistant from a point. It has symbol S5, and the equation for the 5-sphere, radius r, centre the origin is

S^{5}=\left\{x\in {\mathbb  {R}}^{6}:\|x\|=r\right\}.

The volume of six-dimensional space bounded by this 5-sphere is

V_{6}={\frac  {\pi ^{3}r^{6}}{6}}

which is 5.16771 × r6, or 0.0807 of the smallest 6-cube that contains the 5-sphere.

6-sphere

The 6-sphere, or hypersphere in seven dimensions, is the six-dimensional surface equidistant from a point. It has symbol S6, and the equation for the 6-sphere, radius r, centre the origin is

S^{6}=\left\{x\in {\mathbb  {R}}^{7}:\|x\|=r\right\}.

The volume of the space bounded by this 6-sphere is

V_{7}={\frac  {16\pi ^{3}r^{7}}{105}}

which is 4.72477 × r7, or 0.0369 of the smallest 7-cube that contains the 6-sphere.

Applications

Transformations in three dimensions

In three dimensional space a generalised transformation has six degrees of freedom, three translations along the three coordinate axes and three from the rotation group SO(3). Often these transformations are handled separately as they have very different geometrical structures, but there are ways of dealing with them that treat them as a single six-dimensional object.

Homogeneous coordinates

Using four dimensional Homogeneous coordinates it is possible to describe a general transformation using a single 4 × 4 matrix. This matrix has six degrees of freedom, which can identified with the six elements of the matrix above the main diagonal, as all others are determined by these.

Screw theory

In screw theory angular and linear velocity are combined into one six-dimensional object, called a twist. A similar object called a wrench combines forces and torques in six dimensions. These can be treated as six-dimensional vectors that transform linearly when changing frame of reference. Translations and rotations cannot be done this way, but are related to a twist by exponentiation.

Phase space

Phase portrait of the Van der Pol oscillator

Phase space is a space made up of the position and momentum of a particle, which can be plotted together in a phase diagram to highlight the relationship between the quantities. A general particle moving in three dimensions has a phase space with six dimensions, too many to plot but they can be analysed mathematically.[1]

Rotations in four dimensions

The rotation group in four dimensions, SO(4), has six degrees of freedom. This can be seen by considering the 4 × 4 matrix that represents a rotation: as it is an orthogonal matrix the matrix is determined, up to a change in sign, by e.g. the six elements above the main diagonal. But this group is not linear, and it has a more complex structure than other applications seen so far.

Another way of looking at this group is with quaternion multiplication. Every rotation in four dimensions can be achieved by multiplying by a pair of unit quaternions, one before and one after the vector. These quaternion are unique, up to a change in sign for both of them, and generate all rotations when used this way, so the product of their groups, S3 × S3, is a double cover of SO(4), which must have six dimensions.

Although the space we live in is considered three-dimensional, there are practical applications for four-dimensional space. Quaternions, one of the ways to describe rotations in three dimensions, consist of a four-dimensional space. Rotations between quaternions, for interpolation for example, take place in four dimensions. Spacetime, which has three space dimensions and one time dimension is also four-dimensional, though with a different structure to Euclidian space.

Plücker coordinates

Plücker coordinates are a way of representing lines in three dimensions using six homogeneous coordinates. As homogeneous coordinates they have only five degrees of freedom, corresponding to the five degrees of freedom of a general line, but they are treated as 6-vectors for some purposes. For example the check for the intersection of two lines is a 6-dimensional dot product between two sets of Plücker coordinates, one of which has exchanged its displacement and moment parts.

Electromagnetism

In electromagnetism, the electromagnetic field is generally thought of as being made of two things, the electric field and magnetic field. They are both three-dimensional vector fields, related to each other by Maxwell's equations. A second approach is to combine them in a single object, the six-dimensional electromagnetic tensor, a tensor or bivector valued representation of the electromagnetic field. Using this Maxwell's equations can be condensed from four equations into a particularly compact single equation:

\partial {\mathbf  {F}}={\mathbf  {J}}\,

where F is the bivector form of the electromagnetic tensor, J is the four-current and is a suitable differential operator.[2]

String theory

Calabi-Yau manifold (3D projection)

In physics string theory is an attempt to describe general relativity and quantum mechanics with a single mathematical model. Although it is an attempt to model our universe it takes place in a space with more dimensions than the four of space-time that we are familiar with. In particular a number of string theories take place in a ten-dimensional space, adding an extra six dimensions. These extra dimensions are required by the theory, but as they cannot be observed are thought to be quite different, perhaps compactified to form a six-dimensional space with a particular geometry too small to be observable.

Since 1997, another string theory has come to light that works in six dimensions. Little string theories are non-gravitational string theories in five and six dimensions that arise when considering limits of ten-dimensional string theory.[3]

Theoretical background

Bivectors in four dimensions

A number of the above applications can be related to each other algebraically by considering the real, six-dimensional bivectors in four dimensions. These can be written Λ24 for the set of bivectors in Euclidian space or Λ23,1 for the set of bivectors in spacetime. The Plücker coordinates are bivectors in ℝ4 while the electromagnetic tensor discussed in the previous section is a bivector in ℝ3,1. Bivectors can be used to generate rotations in either ℝ4 or ℝ3,1 through the exponential map (e.g. applying the exponetial map of all bivectors in Λ24 generates all rotations in ℝ4). They can also be related to general transformations in three dimensions through homogeneous coordinates, which can be thought of as modified rotations in ℝ4.

The bivectors arise from sums of all possible wedge products between pairs of 4-vectors. They therefore have C4
2
 
= 6 components, and can be written most generally as

{\mathbf  {B}}=B_{{12}}{\mathbf  {e}}_{{12}}+B_{{13}}{\mathbf  {e}}_{{13}}+B_{{14}}{\mathbf  {e}}_{{14}}+B_{{23}}{\mathbf  {e}}_{{23}}+B_{{24}}{\mathbf  {e}}_{{24}}+B_{{34}}{\mathbf  {e}}_{{34}}

They are the first bivectors that cannot all be generated by products of pairs of vectors. Those that can are simple bivectors and the rotations they generate are simple rotations. Other rotations in four dimensions are double and isoclinic rotations and correspond to non-simple bivectors that cannot be generated by single wedge product.[4]

6-vectors

6-vectors are simply the vectors of six-dimensional Euclidean space. Like other such vectors they are linear, can be added subtracted and scaled like in other dimensions. Rather than use letters of the alphabet higher dimensions usually use suffixes to designate dimensions, so a general six-dimensional vector can be written a = (a1, a2, a3, a4, a5, a6). Written like this the six basis vectors are (1, 0, 0, 0, 0, 0), (0, 1, 0, 0, 0, 0), (0, 0, 1, 0, 0, 0), (0, 0, 0, 1, 0, 0), (0, 0, 0, 0, 1, 0) and (0, 0, 0, 0, 0, 1).

Of the vector operators the cross product cannot be used in six dimensions; instead the wedge product of two 6-vectors results in a bivector with 15 dimensions. The dot product of two vectors is

{\mathbf  {a}}\cdot {\mathbf  {b}}=a_{1}b_{1}+a_{2}b_{2}+a_{3}b_{3}+a_{4}b_{4}+a_{5}b_{5}+a_{6}b_{6}.

It can be used to find the angle between two vectors and the norm,

\left|{\mathbf  {a}}\right\vert ={\sqrt  {{\mathbf  {a}}\cdot {\mathbf  {a}}}}={\sqrt  {{a_{1}}^{2}+{a_{2}}^{2}+{a_{3}}^{2}+{a_{4}}^{2}+{a_{5}}^{2}+{a_{6}}^{2}}}.

This can be used for example to calculate the diagonal of a 6-cube; with one corner at the origin, edges aligned to the axes and side length 1 the opposite corner could be at (1, 1, 1, 1, 1, 1), the norm of which is

{\sqrt  {1+1+1+1+1+1}}={\sqrt  {6}}=2.4495,

which is the length of the vector and so of the diagonal of the 6-cube.

Complex 3-space

The complex plane C has two real dimensions, so C3 is a six-dimensional space. William Rowan Hamilton identified this space in 1853[5] as the bivectors of is biquaternions. He had introduced vectors as 3-dimensional parts of quaternions, so when the tensor product C\otimes H became biquaternions, the complex 3-dimensional part was bivectors. The exponential map takes bivectors to the unit sphere of the biquaternion algebra, which is isomorphic to the Lorentz group. Hence, as Ronald Shaw and Graham Bowtell[6] have noted, bivectors are logarithms of Lorentz transformations. Generally vector analysis is confined to three dimensions, but in Vector Analysis (1901) the six-dimensional space of bivectors was used by J. W. Gibbs and E. B. Wilson.[7]

In the differential geometry of complex manifolds some six-dimensional spaces arise as algebraic manifolds. Examples include the quintic threefold and the Barth-Nieto quintic. According to Piergiorgio Odifreddi, the classification of complex three-dimensional manifolds "was one of the spectacular results obtained by the Japanese school of geometry of Heisuke Hironaka, Shing Tung Yau, and Shigefumi Mori. For this work they were awarded the Fields Medal in 1970, 1983, and 1990, respectively."[8]

Footnotes

  1. Arthur Besier (1969). Perspectives of Modern Physics. McGraw-Hill. 
  2. Lounesto (2001), pp. 109–110
  3. Aharony (2000)
  4. Lounesto (2001), pp. 86-89
  5. William Rowan Hamilton (1853) Lectures on Quaternions, p 665, Royal Irish Academy, link from Cornell University Historical Mathematics Collection
  6. Ronald Shaw and Graham Bowtell (1969) "The Bivector Logarithm of a Lorentz Transformation", Quarterly Journal of Mathematics 20:497503
  7. Edwin Bidwell Wilson (1901) Vector Analysis, pages 426 to 436, "Harmonic Vibrations and Bivectors"
  8. Piergiorgio Odifreddi (2004) The Mathematical Century, page 82, Princeton University Press ISBN 0-691-09294-X

References

This article is issued from Wikipedia. The text is available under the Creative Commons Attribution/Share Alike; additional terms may apply for the media files.