A
regular tetrahedron (one with all faces being equilateral) cannot be a Heronian tetrahedron because, for regular tetrahedra whose edge lengths are integers, the face areas and volume are
irrational numbers. For the same reason no Heronian tetrahedron can have an
equilateral triangle as one of its faces. There are infinitely many Heronian tetrahedra, and more strongly infinitely many Heronian
disphenoids, tetrahedra in which all faces are congruent and each pair of opposite sides has equal lengths. In this case, there are only three edge lengths needed to describe the tetrahedron, rather than six, and the triples of lengths that define Heronian tetrahedra can be characterized using an
elliptic curve. There are also infinitely many Heronian tetrahedra with a cycle of four equal edge lengths, in which all faces are
isosceles triangles. There are also infinitely many Heronian birectangular tetrahedra. One method for generating tetrahedra of this type derives the axis-parallel edge lengths a, b, and c from two equal
sums of fourth powers :p^4+s^4=q^4+r^4 using the formulas :a=\bigl|(pq)^2-(rs)^2\bigr|, :b=\bigl|2pqrs\bigr|, :c=\bigl|(pr)^2-(qs)^2\bigr|. For instance, the tetrahedron derived in this way from an identity of
Leonhard Euler, 59^4+158^4=133^4+134^4, has a, b, and c equal to , , and , with the
hypotenuse of right triangle ab equal to , the hypotenuse of right triangle bc equal to , and the hypotenuse of the remaining two sides equal to . For these tetrahedra, a, b, and c form the edge lengths of an
almost-perfect cuboid, a rectangular cuboid in which the sides, two of the three face diagonals, and the body diagonal are all integers. A complete classification of all Heronian tetrahedra remains unknown. ==Heronian trirectangular tetrahedron==