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In the theory of algebraic curves, Brill–Noether theory, introduced by , is the study of special divisors, certain divisors on a curve ''C'' that determine more compatible functions than would be predicted. In classical language, special divisors move on the curve in a "larger than expected" linear system of divisors. The condition to be a special divisor ''D'' can be formulated in sheaf cohomology terms, as the non-vanishing of the ''H''1 cohomology of the sheaf of the sections of the invertible sheaf or line bundle associated to ''D''. This means that, by the Riemann–Roch theorem, the ''H''0 cohomology or space of holomorphic sections is larger than expected. Alternatively, by Serre duality, the condition is that there exist holomorphic differentials with divisor ≥ −''D'' on the curve. ==Main theorems of Brill–Noether theory== For given genus ''g'', the moduli space for curves ''C'' of genus ''g'' should contain a dense subset parameterizing those curves with the minimum in the way of special divisors. One goal of the theory is to 'count constants', for those curves: to predict the dimension of the space of special divisors (up to linear equivalence) of a given degree ''d'', as a function of ''g'', that ''must'' be present on a curve of that genus. The basic statement can be formulated in terms of the Picard variety Pic(''C'') of a smooth curve ''C'', and the subset of Pic(''C'') corresponding to divisor classes of divisors ''D'', with given values ''d'' of deg(''D'') and ''r'' of ''l''(''D'') in the notation of the Riemann–Roch theorem. There is a lower bound ρ for the dimension dim(''d'', ''r'', ''g'') of this subscheme in Pic(''C''): :dim(''d'', ''r'', ''g'') ≥ ρ = g − (r+1)(g − d+r) called the Brill–Noether number. For smooth curves ''G'' and for ''d''≥1, ''r''≥0 the basic results about the space ''G'' of linear systems on ''C'' of degree ''d'' and dimension ''r'' are as follows. *Kempf proved that if ρ≥0 then ''G'' is not empty, and every component has dimension at least ρ. *Fulton and Lazarsfeld proved that if ρ≥1 then ''G'' is connected. * showed that if ''C'' is generic then ''G'' is reduced and all components have dimension exactly ρ (so in particular ''G'' is empty if ρ<0). *Gieseker proved that if ''C'' is generic then ''G'' is smooth. By the connectedness result this implies it is irreducible if ''ρ'' > 0. The problem formulation can be carried over into higher dimensions, and there is now a corresponding Brill–Noether theory for some classes of algebraic surfaces. Algebraic geometer Montserrat Teixidor i Bigas has written several papers about this topic, including "Brill–Noether Theory for stable vector bundles'';〔(Brill–Noether Theory for stable vector bundles )〕 "A Riemann Singularity Theorem for generalized Brill–Noether loci";〔(A Riemann Singularity Theorem for generalized Brill–Noether loci )〕 "Brill–Noether theory for vector bundles of rank 2" 〔(Brill–Noether theory for vector bundles of rank 2 )〕 and "Brill–Noether theory for stable vector bundles".〔(Brill–Noether theory for stable vector bundles )〕 抄文引用元・出典: フリー百科事典『 ウィキペディア(Wikipedia)』 ■ウィキペディアで「Brill–Noether theory」の詳細全文を読む スポンサード リンク
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