A cohomology operation is a natural transformation between cohomology functors. For example, if we take cohomology with coefficients in a ring ${\displaystyle R}$ , the cup product squaring operation yields a family of cohomology operations:

${\displaystyle H^{n}(X;R)\to H^{2n}(X;R)}$ 

${\displaystyle x\mapsto x\smile x.}$ 

Cohomology operations need not be homomorphisms of graded rings; see the Cartan formula below.

These operations do not commute with suspension—that is, they are unstable. (This is because if ${\displaystyle Y}$  is a suspension of a space ${\displaystyle X}$ , the cup product on the cohomology of ${\displaystyle Y}$  is trivial.) Steenrod constructed stable operations

${\displaystyle Sq^{i}\colon H^{n}(X;\mathbb {Z} /2)\to H^{n+i}(X;\mathbb {Z} /2)}$ 

for all ${\displaystyle i}$  greater than zero. The notation ${\displaystyle Sq}$  and their name, the Steenrod squares, comes from the fact that ${\displaystyle Sq^{n}}$  restricted to classes of degree ${\displaystyle n}$  is the cup square. There are analogous operations for odd primary coefficients, usually denoted ${\displaystyle P^{i}}$  and called the reduced ${\displaystyle p}$ -th power operations:

${\displaystyle P^{i}\colon H^{n}(X;\mathbb {Z} /p)\to H^{n+2i(p-1)}(X;\mathbb {Z} /p)}$ 

The ${\displaystyle Sq^{i}}$  generate a connected graded algebra over ${\displaystyle \mathbb {Z} /2}$ , where the multiplication is given by composition of operations. This is the mod 2 Steenrod algebra. In the case ${\displaystyle p>2}$ , the mod ${\displaystyle p}$  Steenrod algebra is generated by the ${\displaystyle P^{i}}$  and the Bockstein operation ${\displaystyle \beta }$  associated to the short exact sequence

${\displaystyle 0\to \mathbb {Z} /p\to \mathbb {Z} /p^{2}\to \mathbb {Z} /p\to 0}$ .

In the case ${\displaystyle p=2}$ , the Bockstein element is ${\displaystyle Sq^{1}}$  and the reduced ${\displaystyle p}$ -th power ${\displaystyle P^{i}}$  is ${\displaystyle Sq^{2i}}$ .

As a cohomology ring edit

We can summarize the properties of the Steenrod operations as generators in the cohomology ring of Eilenberg–Maclane spectra

${\displaystyle {\mathcal {A}}_{p}=H\mathbb {F} _{p}^{*}(H\mathbb {F} _{p})}$ ,

since there is an isomorphism

${\displaystyle {\begin{aligned}H\mathbb {F} _{p}^{*}(H\mathbb {F} _{p})&=\bigoplus _{k=0}^{\infty }{\underset {\leftarrow n}{\text{lim}}}\left(H^{n+k}(K(\mathbb {F} _{p},n);\mathbb {F} _{p})\right)\end{aligned}}}$ 

giving a direct sum decomposition of all possible cohomology operations with coefficients in ${\displaystyle \mathbb {F} _{p}}$ . Note the inverse limit of cohomology groups appears because it is a computation in the stable range of cohomology groups of Eilenberg–Maclane spaces. This result^[1] was originally computed^[2] by Cartan (1954–1955, p. 7) and Serre (1953).

Note there is a dual characterization^[3] using homology for the dual Steenrod algebra.

Remark about generalizing to generalized cohomology theories edit

It should be observed if the Eilenberg–Maclane spectrum ${\displaystyle H\mathbb {F} _{p}}$  is replaced by an arbitrary spectrum ${\displaystyle E}$ , then there are many challenges for studying the cohomology ring ${\displaystyle E^{*}(E)}$ . In this case, the generalized dual Steenrod algebra ${\displaystyle E_{*}(E)}$  should be considered instead because it has much better properties and can be tractably studied in many cases (such as ${\displaystyle KO,KU,MO,MU,MSp,\mathbb {S} ,H\mathbb {F} _{p}}$ ).^[4] In fact, these ring spectra are commutative and the ${\displaystyle \pi _{*}(E)}$  bimodules ${\displaystyle E_{*}(E)}$  are flat. In this case, these is a canonical coaction of ${\displaystyle E_{*}(E)}$  on ${\displaystyle E_{*}(X)}$  for any space ${\displaystyle X}$ , such that this action behaves well with respect to the stable homotopy category, i.e., there is an isomorphism

Norman Steenrod and David B. A. Epstein (1962) showed that the Steenrod squares ${\displaystyle Sq^{n}\colon H^{m}\to H^{m+n}}$  are characterized by the following 5 axioms:

1. Naturality: ${\displaystyle Sq^{n}\colon H^{m}(X;\mathbb {Z} /2)\to H^{m+n}(X;\mathbb {Z} /2)}$  is an additive homomorphism and is natural with respect to any ${\displaystyle f\colon X\to Y}$ , so ${\displaystyle f^{*}(Sq^{n}(x))=Sq^{n}(f^{*}(x))}$ .
2. ${\displaystyle Sq^{0}}$  is the identity homomorphism.
3. ${\displaystyle Sq^{n}(x)=x\smile x}$  for ${\displaystyle x\in H^{n}(X;\mathbb {Z} /2)}$ .
4. If ${\displaystyle n>\deg(x)}$  then ${\displaystyle Sq^{n}(x)=0}$ 
5. Cartan Formula: ${\displaystyle Sq^{n}(x\smile y)=\sum _{i+j=n}(Sq^{i}x)\smile (Sq^{j}y)}$ 

In addition the Steenrod squares have the following properties:

• ${\displaystyle Sq^{1}}$  is the Bockstein homomorphism ${\displaystyle \beta }$  of the exact sequence ${\displaystyle 0\to \mathbb {Z} /2\to \mathbb {Z} /4\to \mathbb {Z} /2\to 0.}$ 
• ${\displaystyle Sq^{i}}$  commutes with the connecting morphism of the long exact sequence in cohomology. In particular, it commutes with respect to suspension ${\displaystyle H^{k}(X;\mathbb {Z} /2)\cong H^{k+1}(\Sigma X;\mathbb {Z} /2)}$ 
• They satisfy the Adem relations, described below

Similarly the following axioms characterize the reduced ${\displaystyle p}$ -th powers for ${\displaystyle p>2}$ .

1. Naturality: ${\displaystyle P^{n}\colon H^{m}(X,\mathbb {Z} /p\mathbb {Z} )\to H^{m+2n(p-1)}(X,\mathbb {Z} /p\mathbb {Z} )}$  is an additive homomorphism and natural.
2. ${\displaystyle P^{0}}$  is the identity homomorphism.
3. ${\displaystyle P^{n}}$  is the cup ${\displaystyle p}$ -th power on classes of degree ${\displaystyle 2n}$ .
4. If ${\displaystyle 2n>\deg(x)}$  then ${\displaystyle P^{n}(x)=0}$ 
5. Cartan Formula: ${\displaystyle P^{n}(x\smile y)=\sum _{i+j=n}(P^{i}x)\smile (P^{j}y)}$ 

As before, the reduced p-th powers also satisfy the Adem relations and commute with the suspension and boundary operators.

The Adem relations for ${\displaystyle p=2}$  were conjectured by Wen-tsün Wu (1952) and established by José Adem (1952). They are given by

${\displaystyle Sq^{i}Sq^{j}=\sum _{k=0}^{\lfloor i/2\rfloor }{j-k-1 \choose i-2k}Sq^{i+j-k}Sq^{k}}$ 

for all ${\displaystyle i,j>0}$  such that ${\displaystyle i<2j}$ . (The binomial coefficients are to be interpreted mod 2.) The Adem relations allow one to write an arbitrary composition of Steenrod squares as a sum of Serre–Cartan basis elements.

For odd ${\displaystyle p}$  the Adem relations are

${\displaystyle P^{a}P^{b}=\sum _{i}(-1)^{a+i}{(p-1)(b-i)-1 \choose a-pi}P^{a+b-i}P^{i}}$ 

for a<pb and

${\displaystyle P^{a}\beta P^{b}=\sum _{i}(-1)^{a+i}{(p-1)(b-i) \choose a-pi}\beta P^{a+b-i}P^{i}+\sum _{i}(-1)^{a+i+1}{(p-1)(b-i)-1 \choose a-pi-1}P^{a+b-i}\beta P^{i}}$ 

for ${\displaystyle a\leq pb}$ .

Bullett–Macdonald identities edit

Shaun R. Bullett and Ian G. Macdonald (1982) reformulated the Adem relations as the following identities.

For ${\displaystyle p=2}$  put

${\displaystyle P(t)=\sum _{i\geq 0}t^{i}{\text{Sq}}^{i}}$ 

then the Adem relations are equivalent to

${\displaystyle P(s^{2}+st)\cdot P(t^{2})=P(t^{2}+st)\cdot P(s^{2})}$ 

For ${\displaystyle p>2}$  put

${\displaystyle P(t)=\sum _{i\geq 0}t^{i}{\text{P}}^{i}}$ 

then the Adem relations are equivalent to the statement that

${\displaystyle (1+s\operatorname {Ad} \beta )P(t^{p}+t^{p-1}s+\cdots +ts^{p-1})P(s^{p})}$ 

is symmetric in ${\displaystyle s}$  and ${\displaystyle t}$ . Here ${\displaystyle \beta }$  is the Bockstein operation and ${\displaystyle (\operatorname {Ad} \beta )P=\beta P-P\beta }$ .

There is a nice straightforward geometric interpretation of the Steenrod squares using manifolds representing cohomology classes. Suppose ${\displaystyle X}$  is a smooth manifold and consider a cohomology class ${\displaystyle \alpha \in H^{*}(X)}$  represented geometrically as a smooth submanifold ${\displaystyle f\colon Y\hookrightarrow X}$ . Cohomologically, if we let ${\displaystyle 1=[Y]\in H^{0}(Y)}$  represent the fundamental class of ${\displaystyle Y}$  then the pushforward map

${\displaystyle f_{*}(1)=\alpha }$ 

gives a representation of ${\displaystyle \alpha }$ . In addition, associated to this immersion is a real vector bundle call the normal bundle ${\displaystyle \nu _{Y/X}\to Y}$ . The Steenrod squares of ${\displaystyle \alpha }$  can now be understood — they are the pushforward of the Stiefel–Whitney class of the normal bundle

${\displaystyle Sq^{i}(\alpha )=f_{*}(w_{i}(\nu _{Y/X})),}$ 

which gives a geometric reason for why the Steenrod products eventually vanish. Note that because the Steenrod maps are group homomorphisms, if we have a class ${\displaystyle \beta }$  which can be represented as a sum

${\displaystyle \beta =\alpha _{1}+\cdots +\alpha _{n},}$ 

where the ${\displaystyle \alpha _{k}}$  are represented as manifolds, we can interpret the squares of the classes as sums of the pushforwards of the normal bundles of their underlying smooth manifolds, i.e.,

${\displaystyle Sq^{i}(\beta )=\sum _{k=1}^{n}f_{*}(w_{i}(\nu _{Y_{k}/X})).}$ 

Also, this equivalence is strongly related to the Wu formula.

Complex projective spaces edit

On the complex projective plane ${\displaystyle \mathbf {CP} ^{2}}$ , there are only the following non-trivial cohomology groups,

${\displaystyle H^{0}(\mathbf {CP} ^{2})\cong H^{2}(\mathbf {CP} ^{2})\cong H^{4}(\mathbf {CP} ^{2})\cong \mathbb {Z} }$ ,

as can be computed using a cellular decomposition. This implies that the only possible non-trivial Steenrod product is ${\displaystyle Sq^{2}}$  on ${\displaystyle H^{2}(\mathbf {CP} ^{2};\mathbb {Z} /2)}$  since it gives the cup product on cohomology. As the cup product structure on ${\displaystyle H^{\ast }(\mathbf {CP} ^{2};\mathbb {Z} /2)}$  is nontrivial, this square is nontrivial. There is a similar computation on the complex projective space ${\displaystyle \mathbf {CP} ^{6}}$ , where the only non-trivial squares are ${\displaystyle Sq^{0}}$  and the squaring operations ${\displaystyle Sq^{2i}}$  on the cohomology groups ${\displaystyle H^{2i}}$  representing the cup product. In ${\displaystyle \mathbf {CP} ^{8}}$  the square

${\displaystyle Sq^{2}\colon H^{4}(\mathbf {CP} ^{8};\mathbb {Z} /2)\to H^{6}(\mathbf {CP} ^{8};\mathbb {Z} /2)}$ 

can be computed using the geometric techniques outlined above and the relation between Chern classes and Stiefel–Whitney classes; note that ${\displaystyle f\colon \mathbf {CP} ^{4}\hookrightarrow \mathbf {CP} ^{8}}$  represents the non-zero class in ${\displaystyle H^{4}(\mathbf {CP} ^{8};\mathbb {Z} /2)}$ . It can also be computed directly using the Cartan formula since ${\displaystyle x^{2}\in H^{4}(\mathbf {CP} ^{8})}$  and

${\displaystyle {\begin{aligned}Sq^{2}(x^{2})&=Sq^{0}(x)\smile Sq^{2}(x)+Sq^{1}(x)\smile Sq^{1}(x)+Sq^{2}(x)\smile Sq^{0}(x)\\&=0.\end{aligned}}}$ 

Infinite Real Projective Space edit

The Steenrod operations for real projective spaces can be readily computed using the formal properties of the Steenrod squares. Recall that

${\displaystyle H^{*}(\mathbb {RP} ^{\infty };\mathbb {Z} /2)\cong \mathbb {Z} /2[x],}$ 

where ${\displaystyle \deg(x)=1.}$  For the operations on ${\displaystyle H^{1}}$  we know that

${\displaystyle {\begin{aligned}Sq^{0}(x)&=x\\Sq^{1}(x)&=x^{2}\\Sq^{k}(x)&=0&&{\text{ for any }}k>1\end{aligned}}}$ 

The Cartan relation implies that the total square

${\displaystyle Sq:=Sq^{0}+Sq^{1}+Sq^{2}+\cdots }$ 

is a ring homomorphism

${\displaystyle Sq\colon H^{*}(X)\to H^{*}(X).}$ 

Hence

${\displaystyle Sq(x^{n})=(Sq(x))^{n}=(x+x^{2})^{n}=\sum _{i=0}^{n}{n \choose i}x^{n+i}}$ 

Since there is only one degree ${\displaystyle n+i}$  component of the previous sum, we have that

${\displaystyle Sq^{i}(x^{n})={n \choose i}x^{n+i}.}$ 

Suppose that ${\displaystyle \pi }$  is any degree ${\displaystyle n}$  subgroup of the symmetric group on ${\displaystyle n}$  points, ${\displaystyle u}$  a cohomology class in ${\displaystyle H^{q}(X,B)}$ , ${\displaystyle A}$  an abelian group acted on by ${\displaystyle \pi }$ , and ${\displaystyle c}$  a cohomology class in ${\displaystyle H_{i}(\pi ,A)}$ . Steenrod (1953a, 1953b) showed how to construct a reduced power ${\displaystyle u^{n}/c}$  in ${\displaystyle H^{nq-i}(X,(A\otimes B\otimes \cdots \otimes B)/\pi )}$ , as follows.

1. Taking the external product of ${\displaystyle u}$  with itself ${\displaystyle n}$  times gives an equivariant cocycle on ${\displaystyle X^{n}}$  with coefficients in ${\displaystyle B\otimes \cdots \otimes B}$ .
2. Choose ${\displaystyle E}$  to be a contractible space on which ${\displaystyle \pi }$  acts freely and an equivariant map from ${\displaystyle E\times X}$  to ${\displaystyle X^{n}.}$  Pulling back ${\displaystyle u^{n}}$  by this map gives an equivariant cocycle on ${\displaystyle E\times X}$  and therefore a cocycle of ${\displaystyle E/\pi \times X}$  with coefficients in ${\displaystyle B\otimes \cdots \otimes B}$ .
3. Taking the slant product with ${\displaystyle c}$  in ${\displaystyle H_{i}(E/\pi ,A)}$  gives a cocycle of ${\displaystyle X}$  with coefficients in ${\displaystyle H_{0}(\pi ,A\otimes B\otimes \cdots \otimes B)}$ .

The Steenrod squares and reduced powers are special cases of this construction where ${\displaystyle \pi }$  is a cyclic group of prime order ${\displaystyle p=n}$  acting as a cyclic permutation of ${\displaystyle n}$  elements, and the groups ${\displaystyle A}$  and ${\displaystyle B}$  are cyclic of order ${\displaystyle p}$ , so that ${\displaystyle H_{0}(\pi ,A\otimes B\otimes \cdots \otimes B)}$  is also cyclic of order ${\displaystyle p}$ .

In addition to the axiomatic structure the Steenrod algebra satisfies, it has a number of additional useful properties.

Basis for the Steenrod algebra edit

Jean-Pierre Serre (1953) (for ${\displaystyle p=2}$ ) and Henri Cartan (1954, 1955) (for ${\displaystyle p>2}$ ) described the structure of the Steenrod algebra of stable mod ${\displaystyle p}$  cohomology operations, showing that it is generated by the Bockstein homomorphism together with the Steenrod reduced powers, and the Adem relations generate the ideal of relations between these generators. In particular they found an explicit basis for the Steenrod algebra. This basis relies on a certain notion of admissibility for integer sequences. We say a sequence

${\displaystyle i_{1},i_{2},\ldots ,i_{n}}$ 

is admissible if for each ${\displaystyle j}$ , we have that ${\displaystyle i_{j}\geq 2i_{j+1}}$ . Then the elements

${\displaystyle Sq^{I}=Sq^{i_{1}}\cdots Sq^{i_{n}},}$ 

where ${\displaystyle I}$  is an admissible sequence, form a basis (the Serre–Cartan basis) for the mod 2 Steenrod algebra, called the admissible basis. There is a similar basis for the case ${\displaystyle p>2}$  consisting of the elements

${\displaystyle Sq_{p}^{I}=Sq_{p}^{i_{1}}\cdots Sq_{p}^{i_{n}}}$ ,

such that

${\displaystyle i_{j}\geq pi_{j+1}}$ 

${\displaystyle i_{j}\equiv 0,1{\bmod {2}}(p-1)}$ 

${\displaystyle Sq_{p}^{2k(p-1)}=P^{k}}$ 

${\displaystyle Sq_{p}^{2k(p-1)+1}=\beta P^{k}}$ 

Hopf algebra structure and the Milnor basis edit

The Steenrod algebra has more structure than a graded ${\displaystyle \mathbf {F} _{p}}$ -algebra. It is also a Hopf algebra, so that in particular there is a diagonal or comultiplication map

${\displaystyle \psi \colon A\to A\otimes A}$ 

induced by the Cartan formula for the action of the Steenrod algebra on the cup product. This map is easier to describe than the product map, and is given by

${\displaystyle \psi (Sq^{k})=\sum _{i+j=k}Sq^{i}\otimes Sq^{j}}$ 

${\displaystyle \psi (P^{k})=\sum _{i+j=k}P^{i}\otimes P^{j}}$ 

${\displaystyle \psi (\beta )=\beta \otimes 1+1\otimes \beta }$ .

These formulas imply that the Steenrod algebra is co-commutative.

The linear dual of ${\displaystyle \psi }$  makes the (graded) linear dual ${\displaystyle A_{*}}$  of A into an algebra. John Milnor (1958) proved, for ${\displaystyle p=2}$ , that ${\displaystyle A_{*}}$  is a polynomial algebra, with one generator ${\displaystyle \xi _{k}}$  of degree ${\displaystyle 2^{k}-1}$ , for every k, and for ${\displaystyle p>2}$  the dual Steenrod algebra ${\displaystyle A_{*}}$  is the tensor product of the polynomial algebra in generators ${\displaystyle \xi _{k}}$  of degree ${\displaystyle 2p^{k}-2}$  ${\displaystyle (k\geq 1)}$  and the exterior algebra in generators τ_k of degree ${\displaystyle 2p^{k}-1}$  ${\displaystyle (k\geq 0)}$ . The monomial basis for ${\displaystyle A_{*}}$  then gives another choice of basis for A, called the Milnor basis. The dual to the Steenrod algebra is often more convenient to work with, because the multiplication is (super) commutative. The comultiplication for ${\displaystyle A_{*}}$  is the dual of the product on A; it is given by

${\displaystyle \psi (\xi _{n})=\sum _{i=0}^{n}\xi _{n-i}^{p^{i}}\otimes \xi _{i}.}$  where ${\displaystyle \xi _{0}=1}$ , and

${\displaystyle \psi (\tau _{n})=\tau _{n}\otimes 1+\sum _{i=0}^{n}\xi _{n-i}^{p^{i}}\otimes \tau _{i}}$  if ${\displaystyle p>2}$ .

The only primitive elements of ${\displaystyle A_{*}}$  for ${\displaystyle p=2}$  are the elements of the form ${\displaystyle \xi _{1}^{2^{i}}}$ , and these are dual to the ${\displaystyle Sq^{2^{i}}}$  (the only indecomposables of A).

Relation to formal groups edit

The dual Steenrod algebras are supercommutative Hopf algebras, so their spectra are algebra supergroup schemes. These group schemes are closely related to the automorphisms of 1-dimensional additive formal groups. For example, if ${\displaystyle p=2}$  then the dual Steenrod algebra is the group scheme of automorphisms of the 1-dimensional additive formal group scheme ${\displaystyle x+y}$  that are the identity to first order. These automorphisms are of the form

${\displaystyle x\rightarrow x+\xi _{1}x^{2}+\xi _{2}x^{4}+\xi _{3}x^{8}+\cdots }$ 

The ${\displaystyle p=2}$  Steenrod algebra admits a filtration by finite sub-Hopf algebras. As ${\displaystyle {\mathcal {A}}_{2}}$  is generated by the elements ^[5]

${\displaystyle Sq^{2^{i}}}$ ,

we can form subalgebras ${\displaystyle {\mathcal {A}}_{2}(n)}$  generated by the Steenrod squares

${\displaystyle Sq^{1},Sq^{2},\ldots ,Sq^{2^{n}}}$ ,

giving the filtration

${\displaystyle {\mathcal {A}}_{2}(1)\subset {\mathcal {A}}_{2}(2)\subset \cdots \subset {\mathcal {A}}_{2}.}$ 

These algebras are significant because they can be used to simplify many Adams spectral sequence computations, such as for ${\displaystyle \pi _{*}(ko)}$ , and ${\displaystyle \pi _{*}(tmf)}$ .^[6]

Larry Smith (2007) gave the following algebraic construction of the Steenrod algebra over a finite field ${\displaystyle \mathbb {F} _{q}}$  of order q. If V is a vector space over ${\displaystyle \mathbb {F} _{q}}$  then write SV for the symmetric algebra of V. There is an algebra homomorphism

${\displaystyle {\begin{cases}P(x)\colon SV[[x]]\to SV[[x]]\\P(x)(v)=v+F(v)x=v+v^{q}x&v\in V\end{cases}}}$ 

where F is the Frobenius endomorphism of SV. If we put

${\displaystyle P(x)(f)=\sum P^{i}(f)x^{i}\qquad p>2}$ 

or

${\displaystyle P(x)(f)=\sum Sq^{2i}(f)x^{i}\qquad p=2}$ 

for ${\displaystyle f\in SV}$  then if V is infinite dimensional the elements ${\displaystyle P^{I}}$  generate an algebra isomorphism to the subalgebra of the Steenrod algebra generated by the reduced p′th powers for p odd, or the even Steenrod squares ${\displaystyle Sq^{2i}}$  for ${\displaystyle p=2}$ .

Early applications of the Steenrod algebra were calculations by Jean-Pierre Serre of some homotopy groups of spheres, using the compatibility of transgressive differentials in the Serre spectral sequence with the Steenrod operations, and the classification by René Thom of smooth manifolds up to cobordism, through the identification of the graded ring of bordism classes with the homotopy groups of Thom complexes, in a stable range. The latter was refined to the case of oriented manifolds by C. T. C. Wall. A famous application of the Steenrod operations, involving factorizations through secondary cohomology operations associated to appropriate Adem relations, was the solution by J. Frank Adams of the Hopf invariant one problem. One application of the mod 2 Steenrod algebra that is fairly elementary is the following theorem.

Theorem. If there is a map ${\displaystyle S^{2n-1}\to S^{n}}$  of Hopf invariant one, then n is a power of 2.

The proof uses the fact that each ${\displaystyle Sq^{k}}$  is decomposable for k which is not a power of 2; that is, such an element is a product of squares of strictly smaller degree.

Michael A. Mandell gave a proof of the following theorem by studying the Steenrod algebra (with coefficients in the algebraic closure of ${\displaystyle \mathbb {F} _{p}}$ ):

Theorem. The singular cochain functor with coefficients in the algebraic closure of ${\displaystyle \mathbb {F} _{p}}$  induces a contravariant equivalence from the homotopy category of connected ${\displaystyle p}$ -complete nilpotent spaces of finite ${\displaystyle p}$ -type to a full subcategory of the homotopy category of [[${\displaystyle E_{\infty }}$ -algebras]] with coefficients in the algebraic closure of ${\displaystyle \mathbb {F} _{p}}$ .

The cohomology of the Steenrod algebra is the ${\displaystyle E_{2}}$  term for the (p-local) Adams spectral sequence, whose abutment is the p-component of the stable homotopy groups of spheres. More specifically, the ${\displaystyle E_{2}}$  term of this spectral sequence may be identified as

${\displaystyle \mathrm {Ext} _{A}^{s,t}(\mathbb {F} _{p},\mathbb {F} _{p}).}$ 

This is what is meant by the aphorism "the cohomology of the Steenrod algebra is an approximation to the stable homotopy groups of spheres."

• Pontryagin cohomology operation
• Dual Steenrod algebra
• Cohomology operation

Pedagogical edit

• Malkiewich, Cary, The Steenrod Algebra (PDF), (PDF) from the original on 2017-08-15
• – contains more calculations, such as for Wu manifolds
• – contains interpretations of Ext terms and Streenrod squares

Motivic setting edit

• Reduced power operations in motivic cohomology
• Motivic cohomology with Z/2-coefficients
• Motivic Eilenberg–Maclane spaces
• The homotopy of ${\displaystyle \mathbb {C} }$ -motivic modular forms – relates ${\displaystyle {\mathcal {A}}//{\mathcal {A}}(2)}$  to motivic tmf

References edit

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