In mathematics, Toda–Smith complexes are spectra characterized by having a particularly simple BP-homology, and are useful objects in

stable homotopy theory In mathematics, stable homotopy theory is the part of homotopy theory (and thus algebraic topology) concerned with all structure and phenomena that remain after sufficiently many applications of the suspension functor. A founding result was the F ...

. Toda–Smith complexes provide examples of periodic self maps. These self maps were originally exploited in order to construct infinite families of elements in the homotopy groups of spheres. Their existence pointed the way towards the nilpotence and periodicity theorems.

Mathematical context

The story begins with the degree

p

map on

S^1

(as a circle in the

complex plane In mathematics, the complex plane is the plane formed by the complex numbers, with a Cartesian coordinate system such that the -axis, called the real axis, is formed by the real numbers, and the -axis, called the imaginary axis, is formed by the ...

): :

S^1 \to S^1 \,

z \mapsto z^p \,

The degree

p

map is well defined for

S^k

in general, where

k \in \mathbb

. If we apply the infinite

suspension Suspension or suspended may refer to: Science and engineering * Suspension (topology), in mathematics * Suspension (dynamical systems), in mathematics * Suspension of a ring, in mathematics * Suspension (chemistry), small solid particles suspend ...

functor to this map,

\Sigma^\infty S^1 \to \Sigma^\infty S^1 =: \mathbb^1 \to \mathbb^1

and we take the cofiber of the resulting map: :

S \xrightarrow S \to S/p

We find that

S/p

has the remarkable property of coming from a Moore space (i.e., a designer (co)homology space:

H^n(X) \simeq Z/p

, and

\tilde^*(X)

is trivial for all

* \neq n

). It is also of note that the periodic maps,

\alpha_t

\beta_t

, and

\gamma_t

, come from degree maps between the Toda–Smith complexes,

V(0)_k

V(1)_k

, and

V_2(k)

respectively.

Formal definition

The

n

th Toda–Smith complex,

V(n)

where

n \in -1, 0, 1, 2, 3, \ldots

, is a finite spectrum which satisfies the property that its BP-homology,

BP_*(V(n)) := mathbb^0, BP \wedge V(n) /math>, is isomorphic to BP_*/(p, \ldots, v_n) .

That is, Toda–Smith complexes are completely characterized by their BP -local properties, and are defined as any object V(n) satisfying one of the following equations:

: \begin
BP_*(V(-1)) & \simeq BP_* \\ pt BP_*(V(0)) & \simeq BP_*/p \\ pt BP_*(V(1)) & \simeq BP_*/(p, v_1) \\ pt & \,\,\,\vdots
\end It may help the reader to recall that BP_* = \mathbb_p_1, v_2, ... /math>, \deg v_i = 2(p^i-1) .

Examples of Toda–Smith complexes

* the

sphere spectrum In stable homotopy theory, a branch of mathematics, the sphere spectrum ''S'' is the monoidal unit in the category of spectra. It is the suspension spectrum of ''S''0, i.e., a set of two points. Explicitly, the ''n''th space in the sphere spectrum ...

BP_*(S^0) \simeq BP_*

, which is

V(-1)

. * the mod p Moore spectrum,

BP_*(S/p) \simeq BP_*/p

, which is

V(0)

References

{{DEFAULTSORT:Toda-Smith complex Homotopy theory Homology theory