<p>In [<CitationRef CitationID="CR25">25</CitationRef>], W. Stoll proposed a method of studying holomorphic functions of several complex variables by reducing them to one variable through fiber integration. In this paper, we use this method to extend some important Nevanlinna-type results for holomorphic curves into projective varieties to meromorphic maps from <InlineEquation ID="IEq4"> <EquationSource Format="TEX">\(\mathbb {C}^{p}\)</EquationSource> <EquationSource Format="MATHML"><math> <msup> <mrow> <mi mathvariant="double-struck">C</mi> </mrow> <mi>p</mi> </msup> </math></EquationSource> </InlineEquation> to projective varieties. This includes Bloch’s theorem and Noguchi-Winkelmann-Yamanoi’s Second Main Theorem for holomorphic maps into semi-abelian varieties intersecting an effective divisor, as well as Huynh-Vu-Xie’s Second Main Theorem for meromorphic maps into projective space intersecting with a generic hypersurface with sufficiently high degree.</p>

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Meromorphic Maps from \({\mathbb {C}}^{p}\) into Semi-Abelian Varieties and General Projective Varieties

  • Zhe Wang

摘要

In [25], W. Stoll proposed a method of studying holomorphic functions of several complex variables by reducing them to one variable through fiber integration. In this paper, we use this method to extend some important Nevanlinna-type results for holomorphic curves into projective varieties to meromorphic maps from \(\mathbb {C}^{p}\) C p to projective varieties. This includes Bloch’s theorem and Noguchi-Winkelmann-Yamanoi’s Second Main Theorem for holomorphic maps into semi-abelian varieties intersecting an effective divisor, as well as Huynh-Vu-Xie’s Second Main Theorem for meromorphic maps into projective space intersecting with a generic hypersurface with sufficiently high degree.