In mathematics, given a vector space X with an associated quadratic form q, written (X, q), a null vector or isotropic vector is a non-zero element x of X for which q(x) = 0.
In the theory of real bilinear forms, definite quadratic forms and isotropic quadratic forms are distinct. They are distinguished in that only for the latter does there exist a nonzero null vector.
A quadratic space (X, q) which has a null vector is called a pseudo-Euclidean space. The term isotropic vector v when q(v) = 0 has been used in quadratic spaces, and anisotropic space for a quadratic space without null vectors.
A pseudo-Euclidean vector space may be decomposed (non-uniquely) into orthogonal subspaces A and B, X = A + B, where q is positive-definite on A and negative-definite on B. The null cone, or isotropic cone, of X consists of the union of balanced spheres: The null cone is also the union of the isotropic lines through the origin.
Split algebras
A composition algebra with a null vector is a split algebra.
In a composition algebra (A, +, ×, *), the quadratic form is q(x) = x x*. When x is a null vector then there is no multiplicative inverse for x, and since x ≠ 0, A is not a division algebra.
In the Cayley–Dickson construction, the split algebras arise in the series bicomplex numbers, biquaternions, and bioctonions, which uses the complex number field 
as the foundation of this doubling construction due to L. E. Dickson (1919). In particular, these algebras have two imaginary units, which commute so their product, when squared, yields +1:
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so 1 + hi is a null vector.
The real subalgebras, split complex numbers, split quaternions, and split-octonions, with their null cones representing the light tracking into and out of 0 ∈ A, suggest spacetime topology.
Examples
The light-like vectors of Minkowski space are null vectors.
The four linearly independent biquaternions l = 1 + hi, n = 1 + hj, m = 1 + hk, and m∗ = 1 – hk are null vectors and { l, n, m, m∗ } can serve as a basis for the subspace used to represent spacetime. Null vectors are also used in the Newman–Penrose formalism approach to spacetime manifolds.
In the Verma module of a Lie algebra there are null vectors.
References
- Emil Artin (1957) Geometric Algebra, isotropic
- Arthur A. Sagle & Ralph E. Walde (1973) Introduction to Lie Groups and Lie Algebras, page 197, Academic Press
- Patrick Dolan (1968) A Singularity-free solution of the Maxwell-Einstein Equations, Communications in Mathematical Physics 9(2):161–8, especially 166, link from Project Euclid
- Dubrovin, B. A.; Fomenko, A. T.; Novikov, S. P. (1984). Modern Geometry: Methods and Applications. Translated by Burns, Robert G. Springer. p. 50. ISBN 0-387-90872-2.
- Shaw, Ronald (1982). Linear Algebra and Group Representations. Vol. 1. Academic Press. p. 151. ISBN 0-12-639201-3.
- Neville, E. H. (Eric Harold) (1922). Prolegomena to Analytical Geometry in Anisotropic Euclidean Space of Three Dimensions. Cambridge University Press. p. 204.
In mathematics given a vector space X with an associated quadratic form q written X q a null vector or isotropic vector is a non zero element x of X for which q x 0 A null cone where q x y z x2 y2 z2 displaystyle q x y z x 2 y 2 z 2 In the theory of real bilinear forms definite quadratic forms and isotropic quadratic forms are distinct They are distinguished in that only for the latter does there exist a nonzero null vector A quadratic space X q which has a null vector is called a pseudo Euclidean space The term isotropic vector v when q v 0 has been used in quadratic spaces and anisotropic space for a quadratic space without null vectors A pseudo Euclidean vector space may be decomposed non uniquely into orthogonal subspaces A and B X A B where q is positive definite on A and negative definite on B The null cone or isotropic cone of X consists of the union of balanced spheres r 0 x a b q a q b r a b B displaystyle bigcup r geq 0 x a b q a q b r a b in B The null cone is also the union of the isotropic lines through the origin Split algebrasA composition algebra with a null vector is a split algebra In a composition algebra A the quadratic form is q x x x When x is a null vector then there is no multiplicative inverse for x and since x 0 A is not a division algebra In the Cayley Dickson construction the split algebras arise in the series bicomplex numbers biquaternions and bioctonions which uses the complex number field C displaystyle mathbb C as the foundation of this doubling construction due to L E Dickson 1919 In particular these algebras have two imaginary units which commute so their product when squared yields 1 hi 2 h2i2 1 1 1 displaystyle hi 2 h 2 i 2 1 1 1 Then 1 hi 1 hi 1 hi 1 hi 1 hi 2 0 displaystyle 1 hi 1 hi 1 hi 1 hi 1 hi 2 0 so 1 hi is a null vector The real subalgebras split complex numbers split quaternions and split octonions with their null cones representing the light tracking into and out of 0 A suggest spacetime topology ExamplesThe light like vectors of Minkowski space are null vectors The four linearly independent biquaternions l 1 hi n 1 hj m 1 hk and m 1 hk are null vectors and l n m m can serve as a basis for the subspace used to represent spacetime Null vectors are also used in the Newman Penrose formalism approach to spacetime manifolds In the Verma module of a Lie algebra there are null vectors ReferencesEmil Artin 1957 Geometric Algebra isotropic Arthur A Sagle amp Ralph E Walde 1973 Introduction to Lie Groups and Lie Algebras page 197 Academic Press Patrick Dolan 1968 A Singularity free solution of the Maxwell Einstein Equations Communications in Mathematical Physics 9 2 161 8 especially 166 link from Project Euclid Dubrovin B A Fomenko A T Novikov S P 1984 Modern Geometry Methods and Applications Translated by Burns Robert G Springer p 50 ISBN 0 387 90872 2 Shaw Ronald 1982 Linear Algebra and Group Representations Vol 1 Academic Press p 151 ISBN 0 12 639201 3 Neville E H Eric Harold 1922 Prolegomena to Analytical Geometry in Anisotropic Euclidean Space of Three Dimensions Cambridge University Press p 204
