Regular embedding

In algebraic geometry, a closed immersion $i:X\hookrightarrow Y$ of schemes is a regular embedding of codimension r if each point x in X has an open affine neighborhood U in Y such that the ideal of $X\cap U$ is generated by a regular sequence of length r. A regular embedding of codimension one is precisely an effective Cartier divisor.

Examples and usage

For example, if X and Y are smooth over a scheme S and if i is an S-morphism, then i is a regular embedding. In particular, every section of a smooth morphism is a regular embedding.^[1] If $\operatorname {Spec} B$ is regularly embedded into a regular scheme, then B is a complete intersection ring.^[2]

The notion is used, for instance, in an essential way in Fulton's approach to intersection theory. The important fact is that when i is a regular embedding, if I is the ideal sheaf of X in Y, then the normal sheaf, the dual of $I/I^{2}$ , is locally free (thus a vector bundle) and the natural map $\operatorname {Sym} (I/I^{2})\to \oplus _{0}^{\infty }I^{n}/I^{n+1}$ is an isomorphism: the normal cone $\operatorname {Spec} (\oplus _{0}^{\infty }I^{n}/I^{n+1})$ coincides with the normal bundle.

Non-examples

One non-example is a scheme which isn't equidimensional. For example, the scheme

X={\text{Spec}}\left({\frac {\mathbb {C} [x,y,z]}{(xz,yz)}}\right)

is the union of $\mathbb {A} ^{2}$ and $\mathbb {A} ^{1}$ . Then, the embedding $X\hookrightarrow \mathbb {A} ^{3}$ isn't regular since taking any non-origin point on the $z$ -axis is of dimension $1$ while any non-origin point on the $xy$ -plane is of dimension $2$ .

Local complete intersection morphisms and virtual tangent bundles

A morphism of finite type $f:X\to Y$ is called a (local) complete intersection morphism if each point x in X has an open affine neighborhood U so that f |_U factors as $U{\overset {j}{\to }}V{\overset {g}{\to }}Y$ where j is a regular embedding and g is smooth. ^[3] For example, if f is a morphism between smooth varieties, then f factors as $X\to X\times Y\to Y$ where the first map is the graph morphism and so is a complete intersection morphism. Notice that this definition is compatible with the one in EGA IV for the special case of flat morphisms.^[4]

Let $f:X\to Y$ be a local-complete-intersection morphism that admits a global factorization: it is a composition $X{\overset {i}{\hookrightarrow }}P{\overset {p}{\to }}Y$ where $i$ is a regular embedding and $p$ a smooth morphism. Then the virtual tangent bundle is an element of the Grothendieck group of vector bundles on X given as:^[5]

Failed to parse (SVG (MathML can be enabled via browser plugin): Invalid response ("Math extension cannot connect to Restbase.") from server "http://localhost:6011/en.wikipedia.org/v1/":): {\displaystyle T_f = [i^* T_{P/Y}] - [N_{X/P}]} ,

where $T_{P/Y}=\Omega _{P/Y}^{\vee }$ is the relative tangent sheaf of $p$ (which is locally free since $p$ is smooth) and $N$ is the normal sheaf $({\mathcal {I}}/{\mathcal {I}}^{2})^{\vee }$ (where ${\mathcal {I}}$ is the ideal sheaf of $X$ in $P$ ), which is locally free since $i$ is a regular embedding.

More generally, if $f\colon X\rightarrow Y$ is a any local complete intersection morphism of schemes, its cotangent complex $L_{X/Y}$ is perfect of Tor-amplitude [-1,0]. If moreover $f$ is locally of finite type and $Y$ locally Noetherian, then the converse is also true.^[6]

These notions are used for instance in the Grothendieck–Riemann–Roch theorem.

Non-Noetherian case

SGA 6 Exposé VII uses the following slightly weaker form of the notion of a regular embedding, which agrees with the one presented above for Noetherian schemes:

First, given a projective module E over a commutative ring A, an A-linear map $u:E\to A$ is called Koszul-regular if the Koszul complex determined by it is acyclic in dimension > 0 (consequently, it is a resolution of the cokernel of u).^[7] Then a closed immersion $X\hookrightarrow Y$ is called Koszul-regular if the ideal sheaf determined by it is such that, locally, there are a finite free A-module E and a Koszul-regular surjection from E to the ideal sheaf.^[8]

It is this Koszul regularity that was used in SGA 6 ^[9] for the definition of local complete intersection morphisms; it is indicated there that Koszul-regularity was intended to replace the definition given earlier in this article and that had appeared originally in the already published EGA IV.^[10]

(This questions arises because the discussion of zero-divisors is tricky for non-Noetherian rings in that one cannot use the theory of associated primes.)

Notes

^ Sernesi 2006, D. Notes 2.
^ Sernesi 2006, D.1.
^ SGA 6 1971, Exposé VIII, Definition 1.1.; Sernesi 2006, D.2.1.
^ EGA IV 1967, Definition 19.3.6, p. 196
^ Fulton 1998, Appendix B.7.5.
^ Illusie 1971, Proposition 3.2.6 , p. 209
^ SGA 6 1971, Exposé VII. Definition 1.1. NB: We follow the terminology of the Stacks project.[1]
^ SGA 6 1971, Exposé VII, Definition 1.4.
^ SGA 6 1971, Exposé VIII, Definition 1.1.
^ EGA IV 1967, § 16 no 9, p. 45