The square knot is
amphichiral, meaning that it is indistinguishable from its own mirror image. The
crossing number of a square knot is six, which is the smallest possible crossing number for a composite knot. The
Alexander polynomial of the square knot is :\Delta(t) = (t - 1 + t^{-1})^2, \, which is simply the
square of the Alexander polynomial of a trefoil knot. Similarly, the
Alexander–Conway polynomial of a square knot is :\nabla(z) = (z^2+1)^2. These two polynomials are the same as those for the granny knot. However, the
Jones polynomial for the square knot is :V(q) = (q^{-1} + q^{-3} - q^{-4})(q + q^3 - q^4) = -q^3 + q^2 - q + 3 - q^{-1} + q^{-2} - q^{-3}. \, This is the product of the Jones polynomials for the right-handed and left-handed trefoil knots, and is different from the Jones polynomial for a granny knot. The
knot group of the square knot is given by the presentation :\langle x, y, z \mid x y x = y x y, x z x = z x z \rangle. \, This is
isomorphic to the knot group of the granny knot, and is the simplest example of two different knots with isomorphic knot groups. Unlike the granny knot, the square knot is a
ribbon knot, and it is therefore also a
slice knot. ==References==