In mathematics, a split-biquaternion is a hypercomplex number of the form

where w, x, y, and z are split-complex numbers and i, j, and k multiply as in the quaternion group. Since each coefficient w, x, y, z spans two real dimensions, the split-biquaternion is an element of an eight-dimensional vector space. Considering that it carries a multiplication, this vector space is an algebra over the real field, or an algebra over a ring where the split-complex numbers form the ring. This algebra was introduced by William Kingdon Clifford in an 1873 article for the London Mathematical Society. It has been repeatedly noted in mathematical literature since then, variously as a deviation in terminology, an illustration of the tensor product of algebras, and as an illustration of the direct sum of algebras. The split-biquaternions have been identified in various ways by algebraists; see § Synonyms below.

Modern definition

A split-biquaternion is ring isomorphic to the Clifford algebra C0,3(R). This is the geometric algebra generated by three orthogonal imaginary unit basis directions, {e1, e2, e3} under the combination rule

giving an algebra spanned by the 8 basis elements {1, e1, e2, e3, e1e2, e2e3, e3e1, e1e2e3}, with (e1e2)2 = (e2e3)2 = (e3e1)2 = 1 and ω2 = (e1e2e3)2 = +1. The sub-algebra spanned by the 4 elements {1, i = e1, j = e2, k = e1e2} is the division ring of Hamilton's quaternions, H = C0,2(R). One can therefore see that

where D = C1,0(R) is the algebra spanned by {1, ω}, the algebra of the split-complex numbers. Equivalently,

Split-biquaternion group

The split-biquaternions form an associative ring as is clear from considering multiplications in its basis {1, ω, i, j, k, ωi, ωj, ωk}. When ω is adjoined to the quaternion group one obtains a 16 element group

( {1, i, j, k, 1, i, j, k, ω, ωi, ωj, ωk, ω, ωi, ωj, ωk}, × ).

Direct sum of two quaternion rings

The direct sum of the division ring of quaternions with itself is denoted . The product of two elements and is in this direct sum algebra.

Proposition: The algebra of split-biquaternions is isomorphic to

proof: Every split-biquaternion has an expression q = w + z ω where w and z are quaternions and ω2 = +1. Now if p = u + v ω is another split-biquaternion, their product is

The isomorphism mapping from split-biquaternions to is given by

In , the product of these images, according to the algebra-product of indicated above, is

This element is also the image of pq under the mapping into Thus the products agree, the mapping is a homomorphism; and since it is bijective, it is an isomorphism.

Though split-biquaternions form an eight-dimensional space like Hamilton's biquaternions, on the basis of the Proposition it is apparent that this algebra splits into the direct sum of two copies of the real quaternions.

Hamilton biquaternion

The split-biquaternions should not be confused with the (ordinary) biquaternions previously introduced by William Rowan Hamilton. Hamilton's biquaternions are elements of the algebra


The following terms and compounds refer to the split-biquaternion algebra:

See also


    • Clifford, W.K. (1873) Preliminary Sketch of Biquaternions, pages 195–7 in Mathematical Papers via Internet Archive
    • Clifford, W.K. (1882) The Classification of Geometric Algebras, page 401 in Mathematical Papers, R. Tucker editor
    • Girard, P.R. (1984). "The quaternion group and modern physics". Eur. J. Phys. 5 (1): 25–32. doi:10.1088/0143-0807/5/1/007.
    • Rooney, Joe (2007). "William Kingdon Clifford". In Ceccarelli, Marco (ed.). Distinguished Figures in Mechanism and Machine Science: Their Contributions and Legacies. Springer. pp. 79–. ISBN 978-1-4020-6366-4.
    • Joly, Charles Jasper (1905). A Manual of Quaternions. Macmillan. p. 21.
    • Rosenfeld, Boris (1997). Geometry of Lie Groups. Kluwer. p. 48. ISBN 978-0-7923-4390-5.
    • Bourbaki, N. (2013) [1994]. Elements of the History of Mathematics. Translated by Meldrum, J. Springer. p. 137. ISBN 978-3-642-61693-8.
    • van der Waerden, B. L. (1985). A History of Algebra. Springer. p. 188. ISBN 978-0-387-13610-3.
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