In mathematics, the theorem of Bertini is an existence and genericity theorem for smooth connected hyperplane sections for smooth projective varieties over algebraically closed fields, introduced by Eugenio Bertini. This is the simplest and broadest of the "Bertini theorems" applying to a linear system of divisors; simplest because there is no restriction on the characteristic of the underlying field, while the extensions require characteristic 0.[1]
Pn
|H|
Pn
(Pn)\star
Pn
Pn
The theorem of Bertini states that the set of hyperplanes not containing X and with smooth intersection with X contains an open dense subset of the total system of divisors
|H|
\dim(X)\ge2
The theorem hence asserts that a general hyperplane section not equal to X is smooth, that is: the property of smoothness is generic.
Over an arbitrary field k, there is a dense open subset of the dual space
(Pn)\star
Over a finite field, the above open subset may not contain rational points and in general there is no hyperplanes with smooth intersection with X. However, if we take hypersurfaces of sufficiently big degrees, then the theorem of Bertini holds.[2]
We consider the subfibration of the product variety
X x |H|
x\inX
The rank of the fibration in the product is one less than the codimension of
X\subsetPn
n
|H|
Over any infinite field
k
k
f:X → Pn
f-1(H)
(Pn)\star
The theorem of Bertini has been generalized in various ways. For example, a result due to Steven Kleiman asserts the following (cf. Kleiman's theorem): for a connected algebraic group G, and any homogeneous G-variety X, and two varieties Y and Z mapping to X, let Yσ be the variety obtained by letting σ ∈ G act on Y. Then, there is an open dense subscheme H of G such that for σ ∈ H,
Y\sigma x XZ
Y\sigma x XZ
\sigma\inH
X=Pn
Theorem of Bertini has also been generalized to discrete valuation domains or finite fields, or for étale coverings of X.
The theorem is often used for induction steps.