In mathematics, biquandles and biracks are sets with binary operations that generalize quandles and racks. Biquandles take, in the theory of virtual knots, the place that quandles occupy in the theory of classical knots. Biracks and racks have the same relation, while a biquandle is a birack which satisfies some additional conditions.
Definitions
editBiquandles and biracks have two binary operations on a set written and . These satisfy the following three axioms:
1.
2.
3.
These identities appeared in 1992 in reference [FRS] where the object was called a species.
The superscript and subscript notation is useful here because it dispenses with the need for brackets. For example, if we write for and for then the three axioms above become
1.
2.
3.
If in addition the two operations are invertible, that is given in the set there are unique in the set such that and then the set together with the two operations define a birack.
For example, if , with the operation , is a rack then it is a birack if we define the other operation to be the identity, .
For a birack the function can be defined by
Then
1. is a bijection
2.
In the second condition, and are defined by and . This condition is sometimes known as the set-theoretic Yang-Baxter equation.
To see that 1. is true note that defined by
is the inverse to
To see that 2. is true let us follow the progress of the triple under . So
On the other hand, . Its progress under is
Any satisfying 1. 2. is said to be a switch (precursor of biquandles and biracks).
Examples of switches are the identity, the twist and where is the operation of a rack.
A switch will define a birack if the operations are invertible. Note that the identity switch does not do this.
Biquandles
editA biquandle is a birack which satisfies some additional structure, as described by Nelson and Rische.[1] The axioms of a biquandle are "minimal" in the sense that they are the weakest restrictions that can be placed on the two binary operations while making the biquandle of a virtual knot invariant under Reidemeister moves.
Linear biquandles
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Application to virtual links and braids
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Birack homology
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References
edit- ^ Nelson, Sam; Rische, Jacquelyn L. (2008). "On bilinear biquandles". Colloquium Mathematicum. 112 (2): 279–289. arXiv:0708.1951. doi:10.4064/cm112-2-5.
Further reading
edit- Fenn, Roger; Jordan-Santana, Mercedes; Kauffman, Louis (2004). "Biquandles and Virtual Links". Topology and its Applications. 145 (1–3): 157–175. doi:10.1016/j.topol.2004.06.008.
- Fenn, Roger; Rourke, Colin; Sanderson, Brian (1993). "An Introduction to Species and the Rack Space". Topics in Knot Theory. NATO ASI Series. Vol. 399. Springer. pp. 33–55. doi:10.1007/978-94-011-1695-4_4.
- Kauffman, Louis H. (1999). "Virtual Knot Theory". European Journal of Combinatorics. 20 (7): 663–690. doi:10.1006/eujc.1999.0314.