In the mathematical field of knot theory, the Jones polynomial is a knot polynomial discovered by Vaughan Jones in 1984.^[1][2] Specifically, it is an invariant of an oriented knot or link which assigns to each oriented knot or link a Laurent polynomial in the variable ${\displaystyle t^{1/2}}$ with integer coefficients.^[3]

Suppose we have an oriented link ${\displaystyle L}$, given as a knot diagram. We will define the Jones polynomial ${\displaystyle V(L)}$ by using Louis Kauffman's bracket polynomial, which we denote by ${\displaystyle \langle ~\rangle }$. Here the bracket polynomial is a Laurent polynomial in the variable ${\displaystyle A}$ with integer coefficients.

First, we define the auxiliary polynomial (also known as the normalized bracket polynomial)

${\displaystyle X(L)=(-A^{3})^{-w(L)}\langle L\rangle ,}$

where ${\displaystyle w(L)}$ denotes the writhe of ${\displaystyle L}$ in its given diagram. The writhe of a diagram is the number of positive crossings (${\displaystyle L_{+}}$ in the figure below) minus the number of negative crossings (${\displaystyle L_{-}}$). The writhe is not a knot invariant.

${\displaystyle X(L)}$ is a knot invariant since it is invariant under changes of the diagram of ${\displaystyle L}$ by the three Reidemeister moves. Invariance under type II and III Reidemeister moves follows from invariance of the bracket under those moves. The bracket polynomial is known to change by a factor of ${\displaystyle -A^{\pm 3}}$ under a type I Reidemeister move. The definition of the ${\displaystyle X}$ polynomial given above is designed to nullify this change, since the writhe changes appropriately by ${\displaystyle +1}$ or ${\displaystyle -1}$ under type I moves.

Now make the substitution ${\displaystyle A=t^{-1/4}}$ in ${\displaystyle X(L)}$ to get the Jones polynomial ${\displaystyle V(L)}$. This results in a Laurent polynomial with integer coefficients in the variable ${\displaystyle t^{1/2}}$.

This construction of the Jones polynomial for tangles is a simple generalization of the Kauffman bracket of a link. The construction was developed by Vladimir Turaev and published in 1990.^[4]

Let ${\displaystyle k}$ be a non-negative integer and ${\displaystyle S_{k}}$ denote the set of all isotopic types of tangle diagrams, with ${\displaystyle 2k}$ ends, having no crossing points and no closed components (smoothings). Turaev's construction makes use of the previous construction for the Kauffman bracket and associates to each ${\displaystyle 2k}$-end oriented tangle an element of the free ${\displaystyle \mathrm {R} }$-module ${\displaystyle \mathrm {R} [S_{k}]}$, where ${\displaystyle \mathrm {R} }$ is the ring of Laurent polynomials with integer coefficients in the variable ${\displaystyle t^{1/2}}$.

Jones' original formulation of his polynomial came from his study of operator algebras. In Jones' approach, it resulted from a kind of "trace" of a particular braid representation into an algebra which originally arose while studying certain models, e.g. the Potts model, in statistical mechanics.

Let a link L be given. A theorem of Alexander states that it is the trace closure of a braid, say with n strands. Now define a representation ${\displaystyle \rho }$ of the braid group on n strands, B_n, into the Temperley–Lieb algebra ${\displaystyle \operatorname {TL} _{n}}$ with coefficients in ${\displaystyle \mathbb {Z} [A,A^{-1}]}$ and ${\displaystyle \delta =-A^{2}-A^{-2}}$. The standard braid generator ${\displaystyle \sigma _{i}}$ is sent to ${\displaystyle A\cdot e_{i}+A^{-1}\cdot 1}$, where ${\displaystyle 1,e_{1},\dots ,e_{n-1}}$ are the standard generators of the Temperley–Lieb algebra. It can be checked easily that this defines a representation.

Take the braid word ${\displaystyle \sigma }$ obtained previously from ${\displaystyle L}$ and compute ${\displaystyle \delta ^{n-1}\operatorname {tr} \rho (\sigma )}$ where ${\displaystyle \operatorname {tr} }$ is the Markov trace. This gives ${\displaystyle \langle L\rangle }$, where ${\displaystyle \langle }$ ${\displaystyle \rangle }$ is the bracket polynomial. This can be seen by considering, as Louis Kauffman did, the Temperley–Lieb algebra as a particular diagram algebra.

An advantage of this approach is that one can pick similar representations into other algebras, such as the R-matrix representations, leading to "generalized Jones invariants".

The Jones polynomial is characterized by taking the value 1 on any diagram of the unknot and satisfies the following skein relation:

${\displaystyle (t^{1/2}-t^{-1/2})V(L_{0})=t^{-1}V(L_{+})-tV(L_{-})\,}$

where ${\displaystyle L_{+}}$, ${\displaystyle L_{-}}$, and ${\displaystyle L_{0}}$ are three oriented link diagrams that are identical except in one small region where they differ by the crossing changes or smoothing shown in the figure below:

The definition of the Jones polynomial by the bracket makes it simple to show that for a knot ${\displaystyle K}$, the Jones polynomial of its mirror image is given by substitution of ${\displaystyle t^{-1}}$ for ${\displaystyle t}$ in ${\displaystyle V(K)}$. Thus, an amphicheiral knot, a knot equivalent to its mirror image, has palindromic entries in its Jones polynomial. See the article on skein relation for an example of a computation using these relations.

Another remarkable property of this invariant states that the Jones polynomial of an alternating link is an alternating polynomial. This property was proved by Morwen Thistlethwaite^[5] in 1987. Another proof of this last property is due to Hernando Burgos-Soto, who also gave an extension to tangles^[6] of the property.

The Jones polynomial is not a complete invariant. There exist an infinite number of non-equivalent knots that have the same Jones polynomial. An example of two distinct knots having the same Jones polynomial can be found in the book by Murasugi.^[7]

For a positive integer ${\displaystyle N}$, the ${\displaystyle N}$-colored Jones polynomial ${\displaystyle V_{N}(L,t)}$ is a generalisation of the Jones polynomial. It is the Reshetikhin–Turaev invariant associated with the ${\displaystyle (N+1)}$-irreducible representation of the quantum group ${\displaystyle U_{q}({\mathfrak {sl}}_{2})}$. In this scheme, the Jones polynomial is the 1-colored Jones polynomial, the Reshetikhin-Turaev invariant associated to the standard representation (irreducible and two-dimensional) of ${\displaystyle U_{q}({\mathfrak {sl}}_{2})}$. One thinks of the strands of a link as being "colored" by a representation, hence the name.

More generally, given a link ${\displaystyle L}$ of ${\displaystyle k}$ components and representations ${\displaystyle V_{1},\ldots ,V_{k}}$ of ${\displaystyle U_{q}({\mathfrak {sl}}_{2})}$, the ${\displaystyle (V_{1},\ldots ,V_{k})}$-colored Jones polynomial ${\displaystyle V_{V_{1},\ldots ,V_{k}}(L,t)}$ is the Reshetikhin–Turaev invariant associated to ${\displaystyle V_{1},\ldots ,V_{k}}$ (here we assume the components are ordered). Given two representations ${\displaystyle V}$ and ${\displaystyle W}$, colored Jones polynomials satisfy the following two properties:^[8]

• ${\displaystyle V_{V\oplus W}(L,t)=V_{V}(L,t)+V_{W}(L,t)}$,
• ${\displaystyle V_{V\otimes W}(L,t)=V_{V,W}(L^{2},t)}$, where ${\displaystyle L^{2}}$ denotes the 2-cabling of ${\displaystyle L}$.

These properties are deduced from the fact that colored Jones polynomials are Reshetikhin-Turaev invariants.

Let ${\displaystyle K}$ be a knot. Recall that by viewing a diagram of ${\displaystyle K}$ as an element of the Temperley-Lieb algebra thanks to the Kauffman bracket, one recovers the Jones polynomial of ${\displaystyle K}$. Similarly, the ${\displaystyle N}$-colored Jones polynomial of ${\displaystyle K}$ can be given a combinatorial description using the Jones-Wenzl idempotents, as follows:

• consider the ${\displaystyle N}$-cabling ${\displaystyle K^{N}}$ of ${\displaystyle K}$;
• view it as an element of the Temperley-Lieb algebra;
• insert the Jones-Wenzl idempotents on some ${\displaystyle N}$ parallel strands.

The resulting element of ${\displaystyle \mathbb {Q} (t)}$ is the ${\displaystyle N}$-colored Jones polynomial. See appendix H of ^[9] for further details.

As first shown by Edward Witten,^[10] the Jones polynomial of a given knot ${\displaystyle \gamma }$ can be obtained by considering Chern–Simons theory on the three-sphere with gauge group ${\displaystyle \mathrm {SU} (2)}$, and computing the vacuum expectation value of a Wilson loop ${\displaystyle W_{F}(\gamma )}$, associated to ${\displaystyle \gamma }$, and the fundamental representation ${\displaystyle F}$ of ${\displaystyle \mathrm {SU} (2)}$.

By substituting ${\displaystyle e^{h}}$ for the variable ${\displaystyle t}$ of the Jones polynomial and expanding it as the series of h each of the coefficients turn to be the Vassiliev invariant of the knot ${\displaystyle K}$. In order to unify the Vassiliev invariants (or, finite type invariants), Maxim Kontsevich constructed the Kontsevich integral. The value of the Kontsevich integral, which is the infinite sum of 1, 3-valued chord diagrams, named the Jacobi chord diagrams, reproduces the Jones polynomial along with the ${\displaystyle {\mathfrak {sl}}_{2}}$ weight system studied by Dror Bar-Natan.

By numerical examinations on some hyperbolic knots, Rinat Kashaev discovered that substituting the n-th root of unity into the parameter of the colored Jones polynomial corresponding to the n-dimensional representation, and limiting it as n grows to infinity, the limit value would give the hyperbolic volume of the knot complement. (See Volume conjecture.)

In 2000 Mikhail Khovanov constructed a certain chain complex for knots and links and showed that the homology induced from it is a knot invariant (see Khovanov homology). The Jones polynomial is described as the Euler characteristic for this homology.

It is an open question whether there is a nontrivial knot with Jones polynomial equal to that of the unknot. It is known that there are nontrivial links with Jones polynomial equal to that of the corresponding unlinks by the work of Morwen Thistlethwaite.^[11] It was shown by Kronheimer and Mrowka that there is no nontrivial knot with Khovanov homology equal to that of the unknot.^[12]

• Adams, Colin (2000-12-06). The Knot Book. American Mathematical Society. ISBN 0-8050-7380-9.
• Jones, Vaughan. "The Jones Polynomial" (PDF).
• Jones, Vaughan (1987). "Hecke algebra representations of braid groups and link polynomials". Annals of Mathematics. 126 (2): 335–388. doi:10.2307/1971403. JSTOR 1971403.
• Kauffman, Louis H. (1987). "State models and the Jones polynomial". Topology. 26 (3): 395–407. doi:10.1016/0040-9383(87)90009-7. (explains the definition by bracket polynomial and its relation to Jones' formulation by braid representation)
• Lickorish, W. B. Raymond (1997). An introduction to knot theory. New York; Berlin; Heidelberg; Barcelona; Budapest; Hong Kong; London; Milan; Paris; Santa Clara; Singapore; Tokyo: Springer. p. 175. ISBN 978-0-387-98254-0.
• Thistlethwaite, Morwen (2001). "Links with trivial Jones polynomial". Journal of Knot Theory and Its Ramifications. 10 (4): 641–643. doi:10.1142/S0218216501001050.
• Eliahou, Shalom; Kauffman, Louis H.; Thistlethwaite, Morwen B. (2003). "Infinite families of links with trivial Jones polynomial". Topology. 42 (1): 155–169. doi:10.1016/S0040-9383(02)00012-5.
• Przytycki, Józef H. (1991). "Skein modules of 3-manifolds". Bulletin of the Polish Academy of Sciences. 39 (1–2): 91–100. arXiv:math/0611797.

• "Jones-Conway polynomial", Encyclopedia of Mathematics, EMS Press, 2001 [1994]
• Links with trivial Jones polynomial by Morwen Thistlethwaite
• "The Jones Polynomial", The Knot Atlas.