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Canonical map of low codimensional subvarieties

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 Added by Beorchia Valentina
 Publication date 2004
  fields
and research's language is English




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Fix integers $ageq 1$, $b$ and $c$. We prove that for certain projective varieties $Vsubset{bold P}^r$ (e.g. certain possibly singular complete intersections), there are only finitely many components of the Hilbert scheme parametrizing irreducible, smooth, projective, low codimensional subvarieties $X$ of $V$ such that $$ h^0(X,Cal O_X(aK_X-bH_X)) leq lambda d^{epsilon_1}+c(sum_{1leq h < epsilon_2}p_g(X^{(h)})), $$ where $d$, $K_X$ and $H_X$ denote the degree, the canonical divisor and the general hyperplane section of $X$, $p_g(X^{(h)})$ denotes the geometric genus of the general linear section of $X$ of dimension $h$, and where $lambda$, $epsilon_1$ and $epsilon_2$ are suitable positive real numbers depending only on the dimension of $X$, on $a$ and on the ambient variety $V$. In particular, except for finitely many families of varieties, the canonical map of any irreducible, smooth, projective, low codimensional subvariety $X$ of $V$, is birational.



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