In mathematics, the Whitehead product is a graded quasi-Lie algebra structure on the homotopy groups of a space.
It was defined by J. H. C. Whitehead in (Whitehead 1941).
The relevant MSC code is: 55Q15, Whitehead products and generalizations.
Given elements
, the Whitehead bracket is defined as follows: The product
can be obtained by attaching a
-cell to the wedge sum the attaching map is a map Represent
by maps and then compose their wedge with the attaching map, as The homotopy class of the resulting map does not depend on the choices of representatives, and thus one obtains a well-defined element of Note that there is a shift of 1 in the grading (compared to the indexing of homotopy groups), so
has degree
; equivalently,
(setting L to be the graded quasi-Lie algebra).
acts on each graded component.
The Whitehead product satisfies the following properties: Sometimes the homotopy groups of a space, together with the Whitehead product operation are called a graded quasi-Lie algebra; this is proven in Uehara & Massey (1957) via the Massey triple product.
, then the Whitehead bracket is related to the usual action of
denotes the conjugation of
, this reduces to which is the usual commutator in
This can also be seen by observing that the
-cell of the torus
is attached along the commutator in the
For a path connected H-space, all the Whitehead products on
vanish.
By the previous subsection, this is a generalization of both the facts that the fundamental groups of H-spaces are abelian, and that H-spaces are simple.
All Whitehead products of classes
α ∈
β ∈
lie in the kernel of the suspension homomorphism
This can be shown by observing that the Hopf invariant defines an isomorphism
and explicitly calculating the cohomology ring of the cofibre of a map representing
{\displaystyle [\mathrm {id} _{S^{2}},\mathrm {id} _{S^{2}}]}
Using the Pontryagin–Thom construction there is a direct geometric argument, using the fact that the preimage of a regular point is a copy of the Hopf link.