Contents

Idea

Motivic homotopy theory or $\mathbf{A}^1$-homotopy theory is the homotopy theory of smooth schemes, where the affine line $\mathbf{A}^1$ plays the role of the interval. Hence what is called the motivic homotopy category or the $\mathbb{A}^1$-homotopy category bears the same relation to smooth varieties that the ordinary homotopy category $Ho(Top)$ bears to smooth manifolds.

Both are special cases of a homotopy theory induced by any sufficiently well-behaved interval object $I$ in a site $C$ via localization at that object. Ordinary homotopy theory is obtained by taking $C$ to be the site of smooth manifolds and $I$ to be the real line $\mathbb{R}$, and $\mathbb{A}^1$-homotopy theory over a Noetherian scheme $S$ is obtained when $C$ is the Nisnevich site of smooth schemes of finite type over $S$ and

is the standard affine line in $C$.

As for the standard homotopy theory, one can furthermore pass to spectrum objects and consider the stable homotopy category. In the following we first discuss

• The unstable motivic homotopy category

and then

• The stable motivic homotopy category.

The unstable motivic homotopy category

Let $S$ be a fixed Noetherian base scheme, and let $Sm/S$ be the category of smooth schemes of finite type over $S$.

Thus, a motivic space over $S$ is an (∞,1)-presheaf $F$ on $Sm/S$ such that

• $F$ is an (∞,1)-sheaf for the Nisnevich topology
• $F$ is $\mathbb{A}^1$-homotopy invariant: for every $X\in Sm/S$, the projection $X\times\mathbb{A}^1\to X$ induces an equivalence $F(X)\simeq F(X\times\mathbb{A}^1$).

As for any homotopy localization, the inclusion $\mathrm{H}(S)\subset PSh(Sm/S)$ admits a left adjoint localization functor, and one can show that it preserves finite (∞,1)-products.

The (∞,1)-category $\mathrm{H}(S)$ is a locally presentable and locally cartesian closed (∞,1)-category. However, it is not an (∞,1)-topos (see Remark 3.5 in Spitzweck-Østvær, Motivic twisted K-theory, pdf)

Motivic spheres

The Tate sphere is the pointed object of $\mathrm{H}(S)$ defined by

that is, $T$ is the homotopy cofiber of the inclusion $\mathbb{G}_m\hookrightarrow \mathbb{A}^1$. More generally, any algebraic vector bundle $V$ on $S$ (or, equivalently, any locally free sheaf of finite rank on $S$) has an associated motivic sphere given by its Thom space:

Thus, $T=S^{\mathbb{A}^1}$.

A crucial observation is that $T$ is the suspension of $\mathbb{G}_m$ (pointed at $1$):

Indeed, this follows from the definition of $T$ and the fact that $(\mathbb{A}^1,1)$ is contractible as a pointed motivic space. It is common to write, for $p\geq q\geq 0$,

The stable motivic homotopy category

Thus, a motivic spectrum $E$ is a sequence of pointed motivic spaces $(E_0,E_1,E_2\dots)$ together with equivalences

Since $T\simeq \mathbb{P}^1$, we could equivalently use $\mathbb{P}^1$ instead of $T$ in the above definition.

Since $T\simeq S^1\wedge \mathbb{G}_m$, $SH(S)$ is indeed a stable (∞,1)-category.

Symmetric monoidal structure and universal property

The functor $\Omega^\infty_T\colon SH(S)\to \mathrm{H}_*(S)$ sending a motivic spectrum $E$ to its first component $E_0$ admits a left adjoint $\Sigma_T^\infty$. One can then equip the category $SH(S)$ with the structure of a symmetric monoidal (∞,1)-category in such a way that the (∞,1)-functor $\Sigma_T^\infty$ can be promoted to a symmetric monoidal (∞,1)-functor. As such, $SH(S)$ is characterized by a universal property:

This is (Robalo, Corollary 5.11).

Stable motivic spheres

Because $T\simeq S^{2,1}$, the stable motivic spheres $S^{p,q}$ are defined for all $p,q\in\mathbb{Z}$.

All the other motivic spheres $S^V$, for $V$ a vector bundle on $S$, also become invertible in $SH(S)$. In fact, the Picard ∞-groupoid of $SH(S)$ receives a map from the algebraic K-theory of $S$. These invertible objects are all exotic in the sense that they are not equivalent to any of the “categorical” spheres $S^n = \Sigma^n\Sigma^\infty_T S_+$. These exotic spheres play an important rôle in the formalism of six operations in stable motivic homotopy theory (see Ayoub).

Cohomology theories

Any motivic spectrum $E\in SH(S)$ gives rise to a bigraded cohomology theory for smooth $S$-schemes and more generally for motivic spaces:

as well as a bigraded homology theory:

Main features

The six operations

The categories $SH(S)$ for varying base scheme $S$ support a formalism of six operations. This means that to every morphism of schemes $f: X\to Y$ is associated an (inverse image $\dashv$ direct image)-adjunction

and, if $f$ is separated of finite type, a (direct image with compact support $\dashv$ exceptional inverse image)-adjunction

satisfying the properties listed at six operations. For more details see Ayoub.

Stable homotopy functors. To construct the six operations for $SH$, Voevodsky introduced an axiomatic setting which also subsumes the classical case of étale cohomology. A stable homotopy functor is a contravariant (∞,1)-functor

from some category of schemes to the (∞,1)-category $PrStab (\infty,1) Cat$ of locally presentable stable (∞,1)-categories and colimit-preserving exact functors, satisfying the following axioms (for $f$ a morphism of schemes, we denote $D(f)$ by $f^*$ and its right adjoint by $f_*$):

1. $D(\emptyset)=0$.

2. If $i: X\to Y$ is an immersion of schemes, then $i_*\colon D(X)\to D(Y)$ is fully faithful.

3. (Smooth base change/Beck-Chevalley condition) If $f$ is smooth, then $f^*$ admits a left adjoint $f_\sharp$. Moreover, given a cartesian square

   $$\array{ Y' &\stackrel{k}{\to}& X' \\ _h\downarrow && \downarrow \;_f \\ Y &\stackrel{g}{\to}& X }$$

   with $f$ smooth, there is a canonical equivalence $h_\sharp k^*\simeq g^* f_\sharp$.

4. (Locality) If $i: Z\hookrightarrow X$ is a closed immersion with open complement $j: U\hookrightarrow X$, then the pair $(i^*,j^*)$ is conservative.

5. (Homotopy invariance) If $p: X\times\mathbb{A}^1\to X$ is the projection, then $p^*$ is fully faithful.

6. ($T$-stability) If $p$ is as above and $s$ is the zero section of $p$, then $p_\sharp s_*: D(X)\to D(X)$ is an equivalence of (∞,1)-categories.

For a more precise statement, see Ayoub, Scholie 1.4.2.

This is essentially proved in Morel-Voevodsky 99. In fact, something stronger is expected to be true:

This theorem has not been proved yet; however, Ayoub’s thesis shows that every stable homotopy functor factors through $SH$.

Realization functors

Complex realization. The functor

associating to a smooth $\mathbb{C}$-scheme $X$ its set of $\mathbb{C}$-points with its structure of smooth manifold induces a functor from $\mathrm{H}(\mathbb{C})$ to the homotopy localization of the smooth (∞,1)-topos at the interval object $\mathbb{A}^1(\mathbb{C})\simeq \mathbb{R}^2$. As this localization is equivalent to the (∞,1)-topos $\infty Grpd$ of discrete ∞-groupoids, we obtain the complex realization functor

After $T$-stabilization, we obtain a functor from $SH(\mathbb{C})$ to the (∞,1)-category of spectra, called the complex Betti realization

associating to a smooth $\mathbb{R}$-scheme $X$ its set of $\mathbb{C}$-points with its structure of smooth manifold together with the action of $\mathbb{Z}/2$ by complex conjugation induces as in the complex case the Real realization functor

where $\mathcal{O}_{\mathbb{Z}/2}$ is the orbit category of $\mathbb{Z}/2$. After $T$-stabilization, we obtain a functor from $SH(\mathbb{R})$ to the (∞,1)-category of genuine $\mathbb{Z}/2$-spectra, called the real Betti realization

(see shape of an (∞,1)-topos). However, it does not descend to $\mathrm{H}(k)$ because the étale homotopy type is not $\mathbb{A}^1$-homotopy invariant. To rectify this, we choose a prime $l\neq \operatorname{char}(k)$ and consider the reflexive localization $Pro(\infty Grpd)^\wedge_{l}$ of $Pro(\infty Grpd)$ at the class of maps inducing isomorphisms on pro-homology groups with coefficients in $\mathbb{Z}/l$. We then obtain an étale realization functor

The slice filtration

See motivic slice filtration.

The slice filtration is a filtration of $\mathrm{H}(S)$ and of $SH(S)$ which is analogous to the Postnikov filtration for (∞,1)-topoi. It generalizes the coniveau filtration in algebraic K-theory, the fundamental filtration on Witt groups?, and the weight filtration on mixed Tate motives.

If $S$ is smooth over a field, the layers of the slice filtration of a motivic spectrum (called its slices) are modules over the motivic Eilenberg–Mac Lane spectrum $H(\mathbb{Z})$. At least if $S$ is a field of characteristic zero, this is the same thing as an integral motive. The spectral sequences associated to the slice filtration are analogous to the Atiyah-Hirzebruch spectral sequences in that their first page consists of motivic cohomology groups.

The $\mathbb{A}^1$-Postnikov filtration

One can also consider the filtration on $\mathrm{H}(S)$ induced by the Postnikov filtration in the containing Nisnevich (∞,1)-topos. A motivic space is $\mathbb{A}^1$-n-connected if it is n-connected as a Nisnevich (∞,1)-sheaf, and the $\mathbb{A}^1$-homotopy groups $\pi_n^{\mathbb{A}^1}(X,x)$ of a motivic space are its homotopy groups as a Nisnevich (∞,1)-sheaf.

If $S$ has finite Krull dimension, $\mathbb{A}^1$-homotopy groups detect equivalences because the Nisnevich (∞,1)-topos is hypercomplete.

Intuitively, $\mathbb{A}^1$-connectedness corresponds to the topological connectedness of the real points rather than of the complex points. For example, $\mathbb{G}_m$ is not $\mathbb{A}^1$-connected, and $\mathbb{P}^1$ is $\mathbb{A}^1$-connected but not $\mathbb{A}^1$-simply connected.

This is Morel’s connectivity theorem (Morel, Theorem 5.38). It follows that the $\mathbb{A}^1$-Postnikov filtration on $\mathrm{H}(k)$ “extends” to a t-structure on the stable (∞,1)-category $SH(k)$, called the homotopy t-structure.

Relation to the theory of motives

The stable motivic homotopy category $SH(S)$ is the basis for several definitions of the derived category of mixed motives over $S$. See there for more details.

Relation to the theory of symmetric bilinear forms

Motivic homotopy theory is also related to the classical theory of symmetric bilinear forms (or quadratic forms in characteristic $\neq 2$). Invariants such as Witt groups?, oriented Chow groups, and Hermitian K-theory are representable in the motivic homotopy category.

A central theorem of Fabien Morel states that, if $k$ is a field, the ring of endomorphisms of the motivic sphere spectrum $S^0\in SH(k)$ is canonically isomorphic to the Grothendieck–Witt ring $GW(k)$: this is the group completion of the semiring of isomorphism classes of nondegenerate symmetric bilinear forms over $k$ (Morel, Corollary 5.43). The case $k=\mathbb{R}$ is especially enlightening: there the stable homotopy class of a pointed endomorphism of $\mathbb{P}^1$ corresponds to the nondegenerate symmetric bilinear form over $\mathbb{R}$ whose dimension is the degree of the induced endomorphism of $\mathbb{P}^1(\mathbb{C})\simeq S^2$ and whose signature is the degree of the induced endomorphism of $\mathbb{P}^1(\mathbb{R})\simeq S^1$.

Equivariant motivic homotopy theory

A general theory of equivariant (unstable and stable) motivic homotopy theory was introduced in (Carlsson-Joshua 2014) and further developed in (Hoyois 15).

Applications and examples

$\mathbb{A}^1$-coverings and the $\mathbb{A}^1$-fundamental groupoid

Like the $\mathbb{A}^1$-Postnikov filtration, $\mathbb{A}^1$-coverings and the $\mathbb{A}^1$-fundamental groupoid $\Pi_1^{\mathbb{A}^1}$ are defined in the containing Nisnevich (∞,1)-topos. A morphism of motivic spaces $f: Y\to X$ is an $\mathbb{A}^1$-covering if it is 0-truncated as a morphism between Nisnevich (∞,1)-sheaves. Such a morphism is determined by its 1-truncation $\tau_{\leq 1}f$, and hence there is an equivalence between the category of $\mathbb{A}^1$-coverings of $X$ and that of $\mathbb{A}^1$-invariant objects in the classifying topos of the Nisnevich sheaf of groupoids

This is Morel, Theorem 6.8. The key input for this theorem is the fact that $\Pi_1^{\mathbb{A}^1}(X)$ is $\mathbb{A}^1$-invariant; this is only known for $\mathbb{A}^1$-connected motivic spaces over fields, which explains the hypotheses of the theorem.

When $X$ is a smooth $S$-scheme, examples of $\mathbb{A}^1$-coverings of $X$ include $\mathbb{G}_m$-torsors and finite Galois coverings of degree prime to the characteristics of $X$ (Morel, Lemma 6.5). This can be used to compute some $\mathbb{A}^1$-fundamental groups, for example:

$\mathbb{A}^1$-h-cobordisms and the classification of surfaces

An $\mathbb{A}^1$-h-cobordism is a surjective proper map $X\to\mathbb{A}^1$ in $Sm/S$ such that, for $i=0,1$, the fiber $X_i$ is smooth and the inclusion $X_i\hookrightarrow X$ becomes an equivalence in $\mathrm{H}(S)$.

Asok and Morel used $\mathbb{A}^1$-h-cobordisms to classify rational smooth proper surfaces over algebraically closed fields up to $\mathbb{A}^1$-homotopy. See Asok-Morel.

Euler classes and splittings of algebraic vector bundles

Let $k$ be a perfect field. If $X$ is a smooth affine $k$-scheme, Morel proved that

where $[-,-]$ denote homotopy classes of maps in the motivic homotopy category $\mathrm{H}(k)$, def. . The classical problem of determining whether a rank $n$ vector bundle splits off a trivial line bundle is thus equivalent to determining whether the classifying map $X\to BGL_n$ lifts to $BGL_{n-1}$ in $\mathrm{H}(k)$. If the Nisnevich cohomological dimension of $X$ is at most $n$, we can use obstruction theory together with the fiber sequence

to obtain the following criterion:

The twist by the determinant $\mathrm{det} \xi$ comes from the nontrivial $\mathbb{A}^1$-fundamental group $\pi_1^{\mathbb{A}^1}(BGL_n)=\mathbb{G}_m$.

The Nisnevich sheaf $\pi_{n-1}^{\mathbb{A}^1}(\mathbb{A}^n-0)$ is the n-th Milnor–Witt K-theory sheaf $\mathbf{K}^{MW}_n$, so that

is the n-th oriented Chow group of $X$. When $k$ is algebraically closed, this is just the usual Chow group of $X$ and $e(\xi)$ can be identified with the top Chern class of $\xi$.

Motivic cohomology

Suppose that $S$ is a smooth scheme over a field. Then the motivic cohomology of smooth $S$-schemes is representable in $\mathrm{H}(S)$ and in $SH(S)$. If $A$ is an abelian group and $p\geq q\geq 0$, there exist a pointed motivic spaces $K(A(q),p)$, called a motivic Eilenberg–MacLane space, such that, for every $X\in Sm/S$,

Voevodsky’s cancellation theorem implies that $\Omega_T K(A(q+1), p+2)\simeq K(A(q), p)$. It follows that the sequence of motivic spaces $K(A(n),2n)$ form a $T$-spectrum $H(A)$, called a motivic Eilenberg–MacLane spectrum, such that

If $R$ is a commutative ring, the motivic spectrum $H(R)$ has a canonical structure of $E_\infty$-algebra in $SH(S)$ which induces the ring structure in motivic cohomology.

Unlike in topology, $H(\mathbb{Q})$ is not always equivalent to the rational motivic sphere spectrum $S^0_{\mathbb{Q}}$: this is only the case if $-1$ is a sum of squares in the base field. In general, $H(\mathbb{Q})$ is a direct summand of $S^0_{\mathbb{Q}}$.

The stable (∞,1)-category of $H(\mathbb{Q})$-modules is equivalent to the derived category of mixed motives. See there for more details.

Algebraic K-theory

See algebraic K-theory spectrum.

Algebraic cobordism

See algebraic cobordism.

Related concepts

• equivariant homotopy theory

• motive

• motivic cohomology

• slice spectral sequence

• B1-homotopy theory

• There is an analog of $\mathbb{A}^1$-homotopy theory for other geometries. The extra left adjoint on a cohesive (infinity,1)-topos may realize the localization at an abstract continuum line object. See at cohesion for more details.

References

General

The original references:

• Vladimir Voevodsky, $\mathbf{A}^1$-Homotopy Theory. Proceedings of the International Congress of Mathematicians, Vol. I (Berlin, 1998). Doc. Math. 1998, Extra Vol. I, 579–604 (electronic). web

• Fabien Morel, Vladimir Voevodsky, $\mathbb{A}^1$-homotopy theory of schemes, Publications Mathématiques de l’IHÉS, Volume 90 (1999), p. 45-143 (Numdam:PMIHES_1999__90__45_0 K-Theory:0305 )

• Fabien Morel, $\mathbb{A}^1$-algebraic topology over a field, LNM 2052, 2012, (pdf)

• Aravind Asok, Fabien Morel, Smooth varieties up to $\mathbb{A}^1$-homotopy and algebraic h-cobordisms, Adv. Math. 227 (5) (2011) 1990-2058 [arXiv:0810.0324, doi:10.1016/j.aim.2011.04.009]

Readable introductions to the subject are:

• Bjørn Ian Dundas, Marc Levine, Paul Arne Østvær, Oliver Röndigs, Vladimir Voevodsky, Motivic Homotopy Theory: Lectures at a Summer School in Nordfjordeid, Norway, August 2002, Springer, Universitext, (2006) (doi:10.1007/978-3-540-45897-5)

• Marc Levine, Motivic Homotopy Theory, Milan j. math (2008), (pdf)

• Fabien Morel, An introduction to $\mathbb{A}^1$ homotopy theory, ICTP Trieste July 2002 (directory, pdf, ps)

• Fabien Morel, On the motivic stable π₀ of the sphere spectrum (ps)

• Peter Arndt, Abstract motivic homotopy theory, thesis 2017 (web, pdf, pdf)

  exposition: lecture at Geometry in Modal HoTT, 2019 (recording I, recording II)

Detailed discussion of the model structure on simplicial presheaves on the Nisnevich site and its homotopy localization to A1-homotopy theory:

• John F. Jardine, Local homotopy theory, Springer Monographs in Mathematics (2015) [doi:10.1007/978-1-4939-2300-7]

with brief exposition in:

• John F. Jardine, Motivic spaces and the motivic stable category [pdf, pdf]

For more on the general procedure see homotopy localization.

The universal property of $SH(S)$ is proved in

• Marco Robalo, Noncommutative Motives I: A Universal Characterization of the Motivic Stable Homotopy Theory of Schemes, 2013 (pdf)

For the formalism of six operations see

• Joseph Ayoub, Les six opérations de Grothendieck et le formalisme des cycles évanescants dans le monde motivique PhD thesis, Paris [pdf, K:0761]

• Joseph Ayoub, Les six opérations de Grothendieck et le formalisme des cycles évanescents dans le monde motivique (I), Astérisque 314 (2007) [numdam:AST_2007__314__R1_0]

• Joseph Ayoub, Les six opérations de Grothendieck et le formalisme des cycles évanescents dans le monde motivique (II), Astérisque 315 (2007) [numdam:AST_2007__315__1_0]

• Vladimir Voevodsky, Pierre Deligne, Voevodsky’s lectures on cross functors (pdf)

The slice filtration was defined in

• Vladimir Voevodsky, Open problems in the stable motivic homotopy theory K-theory, 0392 (web pdf)

Representability results:

• Aravind Asok, Marc Hoyois, Matthias Wendt, Affine representability results in $\mathbb{A}^1$-homotopy theory I: Vector bundles, Duke Math. J. 166 10 (2017) 1923-1953 [arXiv:1506.07093, doi:10.1215/00127094-0000014X]

• Aravind Asok, Marc Hoyois, Matthias Wendt, Affine representability results in $\mathbb{A} ^1$-homotopy theory II: principal bundles and homogeneous spaces, Geom. Topol. 22 (2018) 1181-1225 [arXiv:1507.08020, doi:10.2140/gt.2018.22.1181]

Discussion related to étale homotopy:

• Daniel Isaksen, Étale realization of the $\mathbb{A} ^1$-homotopy theory of schemes, Advances in Mathematics 184 (2004)

Discussion about thick ideals:

• Ruth Joachimi?, Thick ideals in equivariant and motivic stable homotopy categories, arXiv:1503.08456.

On (stable) motivic Cohomotopy of schemes (as motivic homotopy classes of maps into motivic Tate spheres):

• Aravind Asok, Jean Fasel, Mrinal Kanti Das, Euler class groups and motivic stable cohomotopy, Journal of the EMS 24 8 (2022) 2775–2822 [arXiv:1601.05723, doi:10.4171/jems/1156]

• Samuel Lerbet, Motivic stable cohomotopy and unimodular rows, Advances in Mathematics 436 109415 (2024) [arXiv:2206.11688, doi:10.1016/j.aim.2023.109415]

Motivic homotopy theory in other contexts

equivariant motivic homotopy theory is developed in

• Gunnar Carlsson, Roy Joshua, Equivariant motivic homotopy theory, arXiv.

This was vastly generalized and studied more thoroughly in

• Marc Hoyois, The six operations in equivariant motivic homotopy theory, Adv. Math. 305 (2017) 197-279 [arXiv:1509.02145, doi:10.1016/j.aim.2016.09.031]

  (cf. Grothendieck's six operations)

Motivic homotopy theory of noncommutative spaces (associative dg-algebras) is studied in

• Marco Robalo, Noncommutative Motives I: A Universal Characterization of the Motivic Stable Homotopy Theory of Schemes, 2013 (pdf)

Motivic homotopy theory of associative nonunital rings is studied in

• Grigory Garkusha, Homotopy theory of associative rings, arXiv:math/0608482.

• Grigory Garkusha, Algebraic Kasparov K-theory. II, arXiv:1206.0178.

See also

• analytic motivic homotopy theory
• logarithmic motivic homotopy theory