Great hexagonal hexecontahedron

The great hexagonal hexecontahedron is a uniform dual polyhedron. It consists of 60 irregular hexagons, each with two short, two medium, and two long edges.

If its dual, the great snub dodecicosidodecahedron, has an edge length of 1, then the hexagon faces have short edge length $$\frac{\sqrt{2\left(\sqrt5-1-2\sqrt{\sqrt5-2}\right)}}{4} ≈ 0.18177$$, medium edge length $$\frac{\sqrt{2\left(\sqrt5-1+2\sqrt{\sqrt5-2}\right)}}{4} ≈ 0.52533$$, and long edge length $$\frac{\sqrt2}{2} ≈ 0.70711$$. The hexagons have one interior angle of $$\arccos\left(-\phi^{-1}\right) ≈ 128.17271°$$, one of $$360°-\arccos\left(\phi^{-1}\right) ≈ 231.82792°$$, and four of 90°, where $$\phi$$ is the golden ratio.

Vertex coordinates
A great hexagonal hexecontahedron with dual edge length 1 has vertex coordinates given by all even permutations of: as well as all even permutations and even sign changes of:
 * $$\left(±\frac{\sqrt{10}-\sqrt2}{8},\,±\frac{\sqrt{10}+\sqrt2}{8},\,0\right),$$
 * $$\left(±\frac{1+\sqrt5}{4},\,±\frac{\sqrt{\sqrt5-1}}{4},\,0\right),$$
 * $$\left(±\frac{\sqrt2}{4},\,±\frac{\sqrt2}{4},\,±\frac{\sqrt2}{4}\right),$$
 * $$\left(\frac{\sqrt{2\left(\sqrt5-2\right)}}{4},\,\frac{\sqrt{2\left(1-2\sqrt{\sqrt5-2}\right)}}{4},\,\frac{\sqrt{2\left(4-\sqrt5+2\sqrt{\sqrt5-2}\right)}}{4}\right),$$
 * $$\left(\frac{\sqrt{10}-\sqrt2}{8},\,\frac{\sqrt{10}-3\sqrt2}{8},\,\frac{\sqrt{\sqrt5-1}}{2}\right),$$
 * $$\left(\frac{\sqrt{2\left(4-\sqrt5-2\sqrt{\sqrt5-2}\right)}}{4},\,\frac{\sqrt{2\left(\sqrt5-2\right)}}{4},\,\frac{\sqrt{2\left(1+2\sqrt{\sqrt5-2}\right)}}{4}\right),$$
 * $$\left(\frac{\sqrt{\sqrt5-1+2\sqrt{2\left(5\sqrt5-1\right)}}}{4},\,-\frac{\sqrt{2\left(3-\sqrt5-\sqrt{2\left(5\sqrt5-1\right)}\right)}}{4},\,\frac{1+\sqrt5}{4}\right),$$
 * $$\left(\frac{\sqrt{\sqrt5-1-2\sqrt{2\left(5\sqrt5-1\right)}}}{4},\,\frac{\sqrt{2\left(3-\sqrt5+\sqrt{2\left(5\sqrt5-1\right)}\right)}}{4},\,\frac{1+\sqrt5}{4}\right).$$