Toda bracket

In mathematics, the Toda bracket is an operation on homotopy classes of maps, in particular on homotopy groups of spheres, named after Hiroshi Toda, who defined them and used them to compute homotopy groups of spheres in (Toda 1962).

See (Kochman 1990) or (Toda 1962) for more information. Suppose that

${\displaystyle W\stackrel{f}{\to }X\stackrel{g}{\to }Y\stackrel{h}{\to }Z}$

is a sequence of maps between spaces, such that the compositions ${\displaystyle g\circ f}$ and ${\displaystyle h\circ g}$ are both nullhomotopic. Given a space ${\displaystyle A}$, let ${\displaystyle CA}$ denote the cone of ${\displaystyle A}$. Then we get a (non-unique) map

${\displaystyle F:CW\to Y}$

induced by a homotopy from ${\displaystyle g\circ f}$ to a trivial map, which when post-composed with ${\displaystyle h}$ gives a map

${\displaystyle h\circ F:CW\to Z}$.

Similarly we get a non-unique map ${\displaystyle G:CX\to Z}$ induced by a homotopy from ${\displaystyle h\circ g}$ to a trivial map, which when composed with ${\displaystyle C_f:CW\to CX}$, the cone of the map ${\displaystyle f}$, gives another map,

${\displaystyle G\circ C_f:CW\to Z}$.

By joining these two cones on ${\displaystyle W}$ and the maps from them to ${\displaystyle Z}$, we get a map

${\displaystyle ⟨f,g,h⟩:SW\to Z}$

representing an element in the group ${\displaystyle [SW,Z]}$ of homotopy classes of maps from the suspension ${\displaystyle SW}$ to ${\displaystyle Z}$, called the Toda bracket of ${\displaystyle f}$, ${\displaystyle g}$, and ${\displaystyle h}$. The map ${\displaystyle ⟨f,g,h⟩}$ is not uniquely defined up to homotopy, because there was some choice in choosing the maps from the cones. Changing these maps changes the Toda bracket by adding elements of ${\displaystyle h[SW,Y]}$ and ${\displaystyle [SX,Z]f}$.

There are also higher Toda brackets of several elements, defined when suitable lower Toda brackets vanish. This parallels the theory of Massey products in cohomology.

The direct sum

${\displaystyle {\pi }_{\ast }^S=\underset{k\ge 0}{⨁}{\pi }_k^S}$

of the stable homotopy groups of spheres is a supercommutative graded ring, where multiplication (called composition product) is given by composition of representing maps, and any element of non-zero degree is nilpotent (Nishida 1973).

If f and g and h are elements of ${\displaystyle {\pi }_{\ast }^S}$ with ${\displaystyle f\cdot g=0}$ and ${\displaystyle g\cdot h=0}$, there is a Toda bracket ${\displaystyle ⟨f,g,h⟩}$ of these elements. The Toda bracket is not quite an element of a stable homotopy group, because it is only defined up to addition of composition products of certain other elements. Hiroshi Toda used the composition product and Toda brackets to label many of the elements of homotopy groups. (Cohen 1968) showed that every element of the stable homotopy groups of spheres can be expressed using composition products and higher Toda brackets in terms of certain well known elements, called Hopf elements.

In the case of a general triangulated category the Toda bracket can be defined as follows. Again, suppose that

${\displaystyle W\stackrel{f}{\to }X\stackrel{g}{\to }Y\stackrel{h}{\to }Z}$

is a sequence of morphism in a triangulated category such that ${\displaystyle g\circ f=0}$ and ${\displaystyle h\circ g=0}$. Let ${\displaystyle C_f}$ denote the cone of f so we obtain an exact triangle

${\displaystyle W\stackrel{f}{\to }X\stackrel{i}{\to }{C}_f\stackrel{q}{\to }W[1]}$

The relation ${\displaystyle g\circ f=0}$ implies that g factors (non-uniquely) through ${\displaystyle C_f}$ as

${\displaystyle X\stackrel{i}{\to }{C}_f\stackrel{a}{\to }Y}$

for some ${\displaystyle a}$. Then, the relation ${\displaystyle h\circ a\circ i=h\circ g=0}$ implies that ${\displaystyle h\circ a}$ factors (non-uniquely) through W[1] as

${\displaystyle C_f\stackrel{q}{\to }W[1]\stackrel{b}{\to }Z}$

for some b. This b is (a choice of) the Toda bracket ${\displaystyle ⟨f,g,h⟩}$ in the group ${\displaystyle \mathrm{hom}(W[1],Z)}$.

There is a convergence theorem originally due to Moss^[1] which states that special Massey products ${\displaystyle ⟨a,b,c⟩}$ of elements in the ${\displaystyle E_r}$-page of the Adams spectral sequence contain a permanent cycle, meaning has an associated element in ${\displaystyle {\pi }_{*}^s(\mathbb{𝕊})}$, assuming the elements ${\displaystyle a,b,c}$ are permanent cycles^{[2]pg 18-19}. Moreover, these Massey products have a lift to a motivic Adams spectral sequence giving an element in the Toda bracket ${\displaystyle ⟨\alpha ,\beta ,\gamma ⟩}$ in ${\displaystyle {\pi }_{*,*}}$ for elements ${\displaystyle \alpha ,\beta ,\gamma }$ lifting ${\displaystyle a,b,c}$.

• Cohen, Joel M. (1968), "The decomposition of stable homotopy.", Annals of Mathematics, Second Series 87 (2): 305–320, doi:10.2307/1970586, PMID 16591550 .
• Kochman, Stanley O. (1990), "Toda brackets", Stable homotopy groups of spheres. A computer-assisted approach, Lecture Notes in Mathematics, 1423, Berlin: Springer-Verlag, pp. 12–34, doi:10.1007/BFb0083797, ISBN 978-3-540-52468-7 .
• "The nilpotency of elements of the stable homotopy groups of spheres", Journal of the Mathematical Society of Japan 25 (4): 707–732, 1973, doi:10.2969/jmsj/02540707, ISSN 0025-5645 .
• Toda, Hiroshi (1962), Composition methods in homotopy groups of spheres, Annals of Mathematics Studies, 49, Princeton University Press, ISBN 978-0-691-09586-8 .

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