In mathematics, the Adams spectral sequence is a spectral sequence introduced by which computes the stable homotopy groups of topological spaces. Like all spectral sequences, it is a computational tool; it relates homology theory to what is now called stable homotopy theory. It is a reformulation using homological algebra, and an extension, of a technique called 'killing homotopy groups' applied by the French school of Henri Cartan and Jean-Pierre Serre.
For everything below, once and for all, we fix a prime p. All spaces are assumed to be CW complexes. The ordinary cohomology groups
H*(X)
H*(X;\Z/p\Z)
The primary goal of algebraic topology is to try to understand the collection of all maps, up to homotopy, between arbitrary spaces X and Y. This is extraordinarily ambitious: in particular, when X is
Sn
[X,Y]
The set
[X,Y]
[X,Y]
[X,Y]
The key idea is that
H*(X)
The point of all this is that A is so large that the above sheet of cohomological data contains all the information we need to recover the p-primary part of [''X'', ''Y''], which is homotopy data. This is a major accomplishment because cohomology was designed to be computable, while homotopy was designed to be powerful. This is the content of the Adams spectral sequence.
X
\pii(X)=0
i<0
\pii(X)
| *,* | |
| E | |
| * |
(X)
| s,t | |
| E | |
| 2 |
=
| s,t | |
| Ext | |
| Ap |
(H*(X),\Z/p)
Ap
p
X
| *,* | |
| E | |
| infty |
\pi*(X) ⊗ \Zp
Note that this implies for
X=S
p
Y
\SigmainftyY
This statement generalizes a little bit further by replacing the
l{A}p
Z/p
H*(Y)
Y
Y
H*(X)
l{A}p
H*(Y)
E2
which has the convergence property of being isomorphic to the graded pieces of a filtration of the
t,s E 2 =Extl{A
s,t p} (H*(X),H*(Y))
p
X
Y
s,t E 2 ⇒
S \pi k ([X,Y]) ⊗ Zp
For example, if we let both spectra be the sphere spectrum, so
X=Y=S
giving a technical tool for approaching a computation of the stable homotopy groups of spheres. It turns out that many of the first terms can be computed explicitly from purely algebraic information[2] pp 23–25. Also note that we can rewrite
t,s E 2 =Extl{A
s,t p} (H*(S),H*(S)) ⇒ \pi*(S) ⊗ Zp
H*(S)=Z/p
E2
We include this calculation information below for
t,s E 2 =\operatorname{Ext}l{A
s,t p} (Z/p,Z/p) ⇒ \pi*(S) ⊗ Zp
p=2
Given the Adams resolution
we have the… \to
*(F H 2) \to
*(F H 1) \to
*(F H 0) \toH*(X)
E1
for the graded Hom-groups. Then the
s,t E 1 =
t \operatorname{Hom} l{A
*(Y)) s),H
E1
so the degree ofE1=\begin{array}{c|ccc} 3&\vdots&\vdots&\vdots\\ 2&Hom2(H
*(F 0), H*(Y))&Hom2(H
*(F 1), H*(Y))&Hom2(H
*(F 2), H*(Y))& … \\ 1&Hom1(H
*(F 0), H*(Y))&Hom1(H
*(F 1), H*(Y))&Hom1(H
*(F 2), H*(Y))& … \\ 0&Hom0(H
*(F 0), H*(Y))&Hom0(H
*(F 1), H*(Y))&Hom0(H
*(F 2), H*(Y))& … \\ \hline&0&1&2 \end{array}
s
The sequence itself is not an algorithmic device, but lends itself to problem solving in particular cases.
The
r
r
.dr\colon
s,t E r \to
s+r,t+r-1 E r
Some of the simplest calculations are with Eilenberg–Maclane spectra such as
X=H\Z
X=H\Z/(pk)
E1
giving a collapsed spectral sequence, hence
s,t E 1 =\begin{cases} \Z/p&ift=s\\ 0&otherwise \end{cases}
E1=Einfty
giving the
s,t Ext l{A
*(H\Z), p}(H \Z/p)=\begin{cases} \Z/p&ift=s\\ 0&ift ≠ s \end{cases}
E2
which ends up giving a splitting in cohomology, soH\Z\xrightarrow{ ⋅ pk}H\Z\toH\Z/pk\to\SigmaH\Z
H*(H\Z/pk)=H*(H\Z) ⊕ H*(\SigmaH\Z)
l{A}p
E2
H*(H\Z/p)
The expected
s,t E 2 =\begin{cases} \Z/p&ift-s=0,1\\ 0&otherwise \end{cases}
Einfty
The only way for this spectral sequence to converge to this page is if is there are non-trivial differentials supported on every element with Adams grading.
s,t E infty =\begin{cases} Z/pk&ift=s\\ 0&otherwise \end{cases}
(s,s+1)
Adams' original use for his spectral sequence was the first proof of the Hopf invariant 1 problem:
\Rn
The Thom isomorphism theorem relates differential topology to stable homotopy theory, and this is where the Adams spectral sequence found its first major use: in 1960, John Milnor and Sergei Novikov used the Adams spectral sequence to compute the coefficient ring of complex cobordism. Further, Milnor and C. T. C. Wall used the spectral sequence to prove Thom's conjecture on the structure of the oriented cobordism ring: two oriented manifolds are cobordant if and only if their Pontryagin and Stiefel–Whitney numbers agree.
Using the spectral sequence above for
X=Y=S
p=2
E2
This can be done by first looking at the Adams resolution of
s,t E 2 =Extl{A
s,t 2} (Z/2,Z/2)
Z/2
Z/2
0
wherel{A}2 ⋅ \iota\toZ/2
l{A}2
0
\iota
K0
SqI\iota
SqI
l{A}2
and we denote each of the generators mapping tooplusIl{A}2 ⋅ SqI\iota\toK0
Sqi\iota
\alphai
| I\alpha | |
| Sq | |
| j |
j
Notice that the last two elements of\begin{align} \alpha1\mapstoSq1\iota&
2\alpha &Sq 1 \mapstoSq2,1\iota\\ \alpha2\mapstoSq2\iota&&
1\alpha Sq 2 \mapstoSq3\iota\\ \alpha4\mapstoSq4\iota&&
3\alpha Sq 1 \mapstoSq3,1\iota\\ \alpha8\mapstoSq8&&
2\alpha Sq 2 \mapstoSq3,1\iota \end{align}
\alphai
| 1\alpha | |
| Sq | |
| 1 |
because of the Adem relation. We call the generator of this element in
1\alpha Sq 1 \mapstoSq1Sq1\iota=0
F2
\beta2
K1
E1
which can be expanded by computer up to degree
s,t E 1 =\begin{array}{c|ccc} \vdots&\vdots&\vdots&\vdots\\ 4&Sq4\iota,Sq3,1\iota&Sq2,1\alpha1,Sq3\alpha1,
2\alpha Sq 2, \alpha4&
2\beta Sq 2 & … \\ 3&Sq3\iota,Sq2,1\iota
2\alpha &Sq 1,
1\alpha Sq 2 &
1\beta Sq 2& … \\ 2&Sq2\iota&\alpha2,
1\alpha Sq 1 &\beta2& … \\ 1&Sq1\iota&\alpha1&0& … \\ 0&\iota&0&0& … \\ \hline&0&1&2 \end{array}
100
E2
s
t-s
E2
The Adams–Novikov spectral sequence is a generalization of the Adams spectral sequence introduced by where ordinary cohomology is replaced by a generalized cohomology theory, often complex bordism or Brown–Peterson cohomology. This requires knowledge of the algebra of stable cohomology operations for the cohomology theory in question, but enables calculations which are completely intractable with the classical Adams spectral sequence.