E∞-Structures on l-Adic Cohomology

For applications to Weil's conjecture, a version of (3.1) is formulated in the setting of algebraic geometry, where M is replaced by an algebraic curve X (defined over an algebraically closed field k) and E by the classifying stack BG of a smooth affine group scheme over X. This chapter lays the groundwork by constructing an analogue of the functor B.

The Trace Formula for BunG(X)

Weil's Conjecture for Function Fields ◽

10.23943/princeton/9780691182148.003.0005 ◽

2019 ◽

pp. 239-308

Author(s):

Dennis Gaitsgory ◽

Jacob Lurie

Keyword(s):

Trace Formula ◽

Algebraic Curve ◽

Group Scheme ◽

Affine Group ◽

Generic Fiber ◽

Prove Theorem ◽

Lefschetz Trace Formula ◽

Moduli Stack ◽

This chapter aims to prove Theorem 1.4.4.1, which is formulated as follows: Theorem 5.0.0.3, let X be an algebraic curve over F q and let G be a smooth affine group scheme over X. Suppose that the fibers of G are connected and that the generic fiber of G is semisimple. Then the moduli stack BunG(X) satisfies the Grothendieck–Lefschetz trace formula. However, Theorem 5.0.0.3 cannot be deduced directly from the Grothendieck–Lefschetz trace formula for global quotient stacks because the moduli stack BunG(X) is usually not quasi-compact. The strategy instead will be to decompose BunG (X) into locally closed substacks BunG(X)[P,ν‎] which are more directly amenable to analysis.

ON THE STRATIFIED VECTOR BUNDLES

International Journal of Mathematics ◽

10.1142/s0129167x09005601 ◽

2009 ◽

Vol 20 (08) ◽

pp. 979-996 ◽

Cited By ~ 1

Author(s):

INDRANIL BISWAS

Keyword(s):

Vector Bundles ◽

Group Scheme ◽

Affine Group ◽

Closed Field ◽

Smooth Variety ◽

Tannakian Category

The stratified vector bundles on a smooth variety defined over an algebraically closed field k form a neutral Tannakian category over k. We investigate the affine group-scheme corresponding to this neutral Tannakian category.

Fibrations with moving cuspidal singularities

Nagoya Mathematical Journal ◽

10.1017/s0027763000003597 ◽

1991 ◽

Vol 122 ◽

pp. 161-179 ◽

Cited By ~ 4

Author(s):

Yoshifumi Takeda

Keyword(s):

Algebraic Geometry ◽

Characteristic Zero ◽

Positive Characteristic ◽

Closed Field ◽

Projective Surface ◽

Projective Curve ◽

Smooth Projective Curve ◽

Smooth Projective Surface ◽

Almost All

Let f: V → C be a fibration from a smooth projective surface onto a smooth projective curve over an algebraically closed field k. In the case of characteristic zero, almost all fibres of f are nonsingular. In the case of positive characteristic, it is, however, known that there exist fibrations whose general fibres have singularities. Moreover, it seems that such fibrations often have pathological phenomena of algebraic geometry in positive characteristic (see M. Raynaud [7], W. Lang [4]).

Journal of K-theory K-theory and its Applications to Algebra Geometry and Topology ◽

Tannakization in derived algebraic geometry

10.1017/is014008019jkt278 ◽

2014 ◽

Vol 14 (3) ◽

pp. 642-700 ◽

Cited By ~ 1

Author(s):

Isamu Iwanari

Keyword(s):

Algebraic Geometry ◽

Galois Group ◽

Monoidal Category ◽

Group Scheme ◽

Affine Group ◽

Stable Category ◽

Group Schemes ◽

Symmetric Monoidal Category ◽

Derived Algebraic Geometry ◽

Mixed Motives

AbstractIn this paper we begin studying tannakian constructions in ∞-categories and combine them with the theory of motivic categories developed by Hanamura, Levine, and Voevodsky. This paper is the first in a series of papers. For the purposes above, we first construct a derived affine group scheme and its representation category from a symmetric monoidal ∞-category, which we shall call the tannakization of a symmetric monoidal ∞-category. It can be viewed as an ∞-categorical generalization of work of Joyal-Street and Nori. Next we apply it to the stable ∞-category of mixed motives equipped with the realization functor of a mixed Weil cohomology. We construct a derived motivic Galois group which represents the automorphism group of the realization functor, and whose representation category satisfies an appropriate universal property. As a consequence, we construct an underived motivic Galois group of mixed motives, which is a pro-algebraic group and has nice properties. Also, we present basic properties of derived affine group schemes in the Appendix.

Homology of SL2 over function fields I: Parabolic subcomplexes

Journal für die reine und angewandte Mathematik (Crelles Journal) ◽

10.1515/crelle-2015-0047 ◽

2018 ◽

Vol 2018 (739) ◽

pp. 159-205

Author(s):

Matthias Wendt

Keyword(s):

Vector Bundles ◽

Function Fields ◽

Equivalence Classes ◽

Isotropy Group ◽

Closed Field ◽

Explicit Formulas ◽

Group Homology ◽

Equivariant Homology ◽

Abstract The present paper studies the group homology of the groups {\operatorname{SL}_{2}(k[C])} and {\operatorname{PGL}_{2}(k[C])} , where {C=\overline{C}\setminus\{P_{1},\dots,P_{s}\}} is a smooth affine curve over an algebraically closed field k. It is well known that these groups act on a product of trees and the quotients can be described in terms of certain equivalence classes of rank two vector bundles on the curve {\overline{C}} . There is a natural subcomplex consisting of cells with suitably non-trivial isotropy group. The paper provides explicit formulas for the equivariant homology of this “parabolic subcomplex”. These formulas also describe group homology of {\operatorname{SL}_{2}(k[C])} above degree s, generalizing a result of Suslin in the case {s=1} .

Smooth affine group schemes over the dual numbers

Épijournal de Géométrie Algébrique ◽

10.46298/epiga.2019.volume3.4792 ◽

2019 ◽

Vol Volume 3 ◽

Author(s):

Matthieu ROMAGNY ◽

Dajano Tossici

Keyword(s):

Commutative Ring ◽

Group Algebra ◽

Group Scheme ◽

Affine Group ◽

Unipotent Group ◽

Dual Numbers ◽

Group Schemes ◽

Weil Restriction ◽

International Audience ◽

International audience We provide an equivalence between the category of affine, smooth group schemes over the ring of generalized dual numbers $k[I]$, and the category of extensions of the form $1 \to \text{Lie}(G, I) \to E \to G \to 1$ where G is an affine, smooth group scheme over k. Here k is an arbitrary commutative ring and $k[I] = k \oplus I$ with $I^2 = 0$. The equivalence is given by Weil restriction, and we provide a quasi-inverse which we call Weil extension. It is compatible with the exact structures and the $\mathbb{O}_k$-module stack structures on both categories. Our constructions rely on the use of the group algebra scheme of an affine group scheme; we introduce this object and establish its main properties. As an application, we establish a Dieudonné classification for smooth, commutative, unipotent group schemes over $k[I]$. Nous construisons une équivalence entre la catégorie des schémas en groupes affines et lisses sur l'anneau des nombres duaux généralisés k[I], et la catégorie des extensions de la forme 1 → Lie(G, I) → E → G → 1 où G est un schéma en groupes affine, lisse sur k. Ici k est un anneau commutatif arbitraire et k[I] = k ⊕ I avec I 2 = 0. L'équivalence est donnée par la restriction de Weil, et nous construisons un foncteur quasi-inverse explicite que nous appelons extension de Weil. Ces foncteurs sont compatibles avec les structures exactes et avec les structures de champs en O k-modules des deux catégories. Nos constructions s'appuient sur le schéma en algèbres de groupe d'un schéma en groupes affines, que nous introduisons et dont nous donnons les propriétés principales. En application, nous donnons une classification de Dieudonné pour les schémas en groupes commutatifs, lisses, unipotents sur k[I] lorsque k est un corps parfait.

Blow Up Sequences and the Module of nth Order Differentials

Canadian Journal of Mathematics ◽

10.4153/cjm-1976-128-9 ◽

1976 ◽

Vol 28 (6) ◽

pp. 1289-1301 ◽

Cited By ~ 1

Author(s):

William C. Brown

Keyword(s):

Singular Point ◽

Local Ring ◽

Algebraic Curve ◽

Blow Up ◽

Quotient Ring ◽

Integral Closure ◽

Closed Field ◽

Quotient Field ◽

Algebraically Closed Field

Let C denote an irreducible, algebraic curve defined over an algebraically closed field k. Let ? be a singular point of C. We shall employ the following notation throughout the rest of this paper: R will denote the local ring at P, K the quotient field of the integral closure of R in K, A the completion of R with respect to its radical topology, and Ā the integral closure of A in its total quotient ring.

On a purely inseparable analogue of the Abhyankar conjecture for affine curves

Compositio Mathematica ◽

10.1112/s0010437x18007194 ◽

2018 ◽

Vol 154 (8) ◽

pp. 1633-1658

Author(s):

Shusuke Otabe

Keyword(s):

Fundamental Group ◽

Positive Characteristic ◽

Smooth Curve ◽

Group Scheme ◽

Partial Answer ◽

Closed Field ◽

Affine Curves ◽

Finite Quotients ◽

Field Of Positive Characteristic

Let$U$be an affine smooth curve defined over an algebraically closed field of positive characteristic. The Abhyankar conjecture (proved by Raynaud and Harbater in 1994) describes the set of finite quotients of Grothendieck’s étale fundamental group$\unicode[STIX]{x1D70B}_{1}^{\acute{\text{e}}\text{t}}(U)$. In this paper, we consider a purely inseparable analogue of this problem, formulated in terms of Nori’s profinite fundamental group scheme$\unicode[STIX]{x1D70B}^{N}(U)$, and give a partial answer to it.

Finite Symmetric Integral Tensor Categories with the Chevalley Property with an Appendix by Kevin Coulembier and Pavel Etingof

International Mathematics Research Notices ◽

10.1093/imrn/rnz093 ◽

2019 ◽

Author(s):

Pavel Etingof ◽

Shlomo Gelaki

Keyword(s):

Hopf Algebras ◽

Tensor Category ◽

Group Scheme ◽

Symmetric Tensor ◽

Closed Field ◽

Characteristic P ◽

Tensor Categories ◽

Finite Dimensional ◽

Chevalley Property

Abstract We prove that every finite symmetric integral tensor category $\mathcal{C}$ with the Chevalley property over an algebraically closed field $k$ of characteristic $p>2$ admits a symmetric fiber functor to the category of supervector spaces. This proves Ostrik’s conjecture [25, Conjecture 1.3] in this case. Equivalently, we prove that there exists a unique finite supergroup scheme $\mathcal{G}$ over $k$ and a grouplike element $\epsilon \in k\mathcal{G}$ of order $\le 2$, whose action by conjugation on $\mathcal{G}$ coincides with the parity automorphism of $\mathcal{G}$, such that $\mathcal{C}$ is symmetric tensor equivalent to $\textrm{Rep}(\mathcal{G},\epsilon )$. In particular, when $\mathcal{C}$ is unipotent, the functor lands in $\textrm{Vec}$, so $\mathcal{C}$ is symmetric tensor equivalent to $\textrm{Rep}(U)$ for a unique finite unipotent group scheme $U$ over $k$. We apply our result and the results of [17] to classify certain finite dimensional triangular Hopf algebras with the Chevalley property over $k$ (e.g., local), in group scheme-theoretical terms. Finally, we compute the Sweedler cohomology of restricted enveloping algebras over an algebraically closed field $k$ of characteristic $p>0$, classify associators for their duals, and study finite dimensional (not necessarily triangular) local quasi-Hopf algebras and finite (not necessarily symmetric) unipotent tensor categories over an algebraically closed field $k$ of characteristic $p>0$. The appendix by K. Coulembier and P. Etingof gives another proof of the above classification results using the recent paper [4], and more generally, shows that the maximal Tannakian and super-Tannakian subcategory of a symmetric tensor category over a field of characteristic $\ne 2$ is always a Serre subcategory.

Stable vector bundles on an algebraic surface

Nagoya Mathematical Journal ◽

10.1017/s0027763000016688 ◽

1975 ◽

Vol 58 ◽

pp. 25-68 ◽

Cited By ~ 38

Author(s):

Masaki Maruyama

Keyword(s):

Vector Bundle ◽

Chern Class ◽

Algebraic Curve ◽

Algebraic Surface ◽

Vector Bundles ◽

Closed Field ◽

Stable Vector Bundles ◽

First Chern Class

Let X be a non-singular projective algebraic curve over an algebraically closed field k. D. Mumford introduced the notion of stable vector bundles on X as follows;DEFINITION ([7]). A vector bundle E on X is stable if and only if for any non-trivial quotient bundle F of E,where deg ( • ) denotes the degree of the first Chern class of a vector bundles and r( • ) denotes the rank of a vector bundle.