Very ampleness of the bicanonical line bundle on compact complex 2-ball quotients

Sai-Kee Yeung

doi:10.1515/forum-2016-0113

Article

Very ampleness of the bicanonical line bundle on compact complex 2-ball quotients

Sai-Kee Yeung

Published/Copyright: July 21, 2017

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From the journal Forum Mathematicum Volume 30 Issue 2

Abstract

The purpose of this note is to show that 2⁢K of any smooth compact complex 2-ball quotient is very ample, except possibly for four pairs of fake projective planes of minimal type, where K is the canonical line bundle. For the four pairs of fake projective planes, the sections of 2⁢KM give an embedding of M except possibly for at most two points on M.

Keywords: Ball quotients; embedding

MSC 2010: 14E25; 14J29

Communicated by Jan Bruinier

Funding source: National Science Foundation

Award Identifier / Grant number: DMS-1501282

Funding statement: The author was partially supported by a grant from the National Science Foundation (grant no. DMS-1501282).

A Appendix

Here we list the fake projective planes according to types discussed in the proof of Theorem 5.1. The naming of the fake projective planes is given according to the naming of Cartwright and Steger in [6]. There are altogether 50 lattices of P⁢U⁢(2,1). Further explanation of the nomenclature can be found in [18, 5].

Table 1

List of cases of fake projective planes.

M	cases
(a=1,p=5,∅,D3)	(b)
(a=1,p=5,{2},D3)	(b)
(a=1,p=5,{2⁢I})	(c)
(a=2,p=3,∅,D3)	(b)
(a=2,p=3,{2},D3))	(b)
(a=2,p=3,{2⁢I})	(c)
(a=7,p=2,∅,D3⁢27)	(b)
(a=7,p=2,∅,721)	(d)
(a=7,p=2,∅,D3⁢X7)	(b)
(a=7,p=2,{7},D3⁢27)	(b)
(a=7,p=2,{7},D3⁢77)	(b)
(a=7,p=2,{7},D3⁢77′)	(b)
(a=7,p=2,{7},721)	(c)
(a=7,p=2,{3},D3)	(b)
(a=7,p=2,{3},33)	(c)
(a=7,p=2,{3,7},D3)	(b)
(a=7,p=2,{3,7},33)	(c)
(a=7,p=2,{5})	min type
(a=7,p=2,{5,7})	min type
(a=15,p=2,∅,D3)	(b)
(a=15,p=2,∅,33)	(c)
(a=15,p=2,{3},D3)	(b)
(a=15,p=2,{3},33)	(b)
(a=15,p=2,{3},(D⁢3)3)	(b)
(a=15,p=2,{5},D3)	(b)

M	cases
(a=15,p=2,{5},33)	(c)
(a=15,p=2,{3,5},D3)	(b)
(a=15,p=2,{3,5},33)	(b)
(a=15,p=2,{3,5},(D⁢3)3)	(b)
(a=23,p=2,∅)	min type
(a=23,p=2,{23})	min type
(𝒞2,p=2,∅,d3⁢D3)	(b)
(𝒞2,p=2,∅,D3⁢X3)	(b)
(𝒞2,p=2,∅,(d⁢D)3⁢X3)	(b)
(𝒞2,p=2,∅,(d2⁢D)3⁢X3)	(b)
(𝒞2,p=2,∅,d3⁢X3′)	(c)
(𝒞2,p=2,∅,X9)	(c)
(𝒞2,p=2,{3},d3⁢D3)	(b)
(𝒞10,p=2,∅,D3)	(b)
(𝒞10,p=2,{17-},D3)	(b)
(𝒞18,p=3,∅,d3⁢D3)	(b)
(𝒞18,p=3,{2},D3)	(b)
(𝒞18,p=3,{2},(d⁢D)3)	(b)
(𝒞18,p=3,{2},(d2⁢D)3)	(b)
(𝒞18,p=3,{2⁢I})	(c)
(𝒞20,{v2},∅,D3⁢27)	(b)
(𝒞20,{v2},{3+},D3)	(b)
(𝒞20,{v2},{3+},{3+}3)	(c)
(𝒞20,{v2},{3-},D3)	(b)
(𝒞20,{v2},{3-},{3-}3)	(c)

Acknowledgements

The author is grateful to Lawrence Ein for raising the question about the Cartwright–Steger surfaces and for explaining the argument of Reider to the author, to Rong Du and Ching-Jui Lai for helpful discussions, to Fabrizio Catanese, and a referee for pointing out a gap in an earlier draft of this paper. It is a pleasure for the author to express his gratitude to the referees for very helpful comments and suggestions on the article.

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Received: 2016-5-4

Revised: 2017-6-9

Published Online: 2017-7-21

Published in Print: 2018-3-1

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Articles in the same Issue

https://doi.org/10.1515/forum-2016-0113

Keywords for this article

Ball quotients; embedding