Difference between revisions of "NTS ABSTRACTFall2022"

From UW-Math Wiki
Jump to navigation Jump to search
Line 16: Line 16:
 
This is based on joint work with Paul Hamacher and Xiaolei Zhao.  
 
This is based on joint work with Paul Hamacher and Xiaolei Zhao.  
  
Zoom ID: 93014934562 Password: The order of A9 (the alternating group of 9 elements)
+
''Zoom ID: 93014934562 Password: The order of A9 (the alternating group of 9 elements)''
 
 
  
 
''Recording for this talk is available upon request. Please email to zyang352@wisc.edu.''  
 
''Recording for this talk is available upon request. Please email to zyang352@wisc.edu.''  

Revision as of 09:47, 1 September 2022

Sep 07

Ziquan Yang
The Tate conjecture for h^{2, 0} = 1 varieties over finite fields

The past decade has witnessed a great advancement on the Tate conjecture for varieties with Hodge number h^{2, 0} = 1. Charles, Madapusi-Pera and Maulik completely settled the conjecture for K3 surfaces over finite fields, and Moonen proved the Mumford-Tate (and hence also Tate) conjecture for more or less arbitrary h^{2, 0} = 1 varieties in characteristic $0$.

In this talk, I will explain that the Tate conjecture is true for mod $p$ reductions of complex projective h^{2, 0} = 1 varieties when p is big enough, under a mild assumption on moduli. By refining this general result, we prove that in characteristic p at least 5 the BSD conjecture holds for a height 1 elliptic curve E over a function field of genus 1, as long as E is subject to the generic condition that all singular fibers in its minimal compacification are irreducible. We also prove the Tate conjecture over finite fields for a class of surfaces of general type and a class of Fano varieties. The overall philosphy is that the connection between the Tate conjecture over finite fields and the Lefschetz $(1, 1)$-theorem over $\IC$ is very robust for h^{2, 0} = 1 varieties, and works well beyond the hyperk\"ahler world.

This is based on joint work with Paul Hamacher and Xiaolei Zhao.

Zoom ID: 93014934562 Password: The order of A9 (the alternating group of 9 elements)

Recording for this talk is available upon request. Please email to zyang352@wisc.edu.