## Where is number theory used in the rest of mathematics?

Where is number theory used in the rest of mathematics?

To put it another way: what interesting questions are there that don't appear to be about number theory, but need number theory in order to answer them?

To put it another way still: imagine a mathematician with no interest in number theory for its own sake. What are some plausible situations where they might, nevertheless, need to learn or use some number theory?

Edit It was swiftly pointed out by Vladimir Dotsenko that the borders between number theory and algebraic geometry, and between number theory and algebra, are long and interesting. One could answer the question in many ways by naming features on that part of the mathematical landscape. But I'd be most interested in hearing about uses for number theory that aren't so obviously near the borders of the subject.

Background In my own work, I often find myself needing to learn bits and pieces of other parts of mathematics. For instance, I've recently needed to learn new bits of analysis, algebra, topology, dynamical systems, geometry, and combinatorics. But I've never found myself needing to learn any number theory.

This might very well just be a consequence of the work I do. I realized, though, that (independently of my own work) I knew of no good answer to the general question in the title. Number theory has such a long and glorious history, with so many spectacular achievements and famous results, that I thought answers should be easy to come by. So I was surprised that I couldn't think of much, and I look forward to other people's answers.

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This is too empty for an answer, so I'll just type a comment. 1) For your third interpretation I have at least one relevant experience of my own - "factor systems" (some) number theorists deal with when talking about central simple algebras over number fields did contribute to the development of homological algebra in general, and learning that somehow expanded my homological algebra horizons a bit. 2) Sometimes, it's hard to say where the border between number theory, commutative algebra, and algebraic geometry lies. Around that "triple point" there should be many potential answers. – Vladimir Dotsenko Mar 9 2012 at 15:05
For instance Number Theory is used in Algebraic Geometry when studying problems in characteristic $p$. But even in characteristic 0, some algebraic varieties arise from arithmetic constructions. Hilbert modular surfaces or Shimura varieties are examples of this situation. Also, the recent classification of fake projective planes by Prasad & Yeung (2007) uses Number Theory in a crucial way. I think there are countless examples like these – Francesco Polizzi Mar 9 2012 at 15:06
Also the study of the Ring of Endomorphisms for abelian varieties needs the understanding of some Number Theory, especially number fields and quaternion algebras. – Francesco Polizzi Mar 9 2012 at 15:09
Thanks very much for the comments. Can I suggest that people write this kind of thing as answers rather than comments, though? That way, replies to your comments are organized more neatly. – Tom Leinster Mar 9 2012 at 15:11
Number theory is used in the representation theory of finite groups to address rationality questions. Algebraic integrality seems to come up just about everywhere. – Grant Rotskoff Mar 9 2012 at 17:37

I believe that has not yet been mentionned the role of quadratic forms over integers in the classification of four manifolds (work of Freedman, Donaldson ...). It is not an example of very "high" number theory but it is a case where number theoretic objects "parametrize" topological or differential geometric objects, relation which seems unexpected at first.

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Well, the Fibonacci sequence belongs to number theory. Doesn't it ? Yet it is fundamental in many parts of Mathematics, at least in sorting algorithms.

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Elliptic curves are the basis for a type of public key cryptography known as elliptic curve cryptography.

Also I attended a colloquium recently that talked about the applications of elliptic curves to string theory.

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It also finds use in the theory of information theory and algorithms (which are essentially mathematical topics); for example, number theoretic transforms are arguably the neatest way of achieving the optimal known complexity for multiplying arbitrarily long integers on a classical computer. Other topics also involving some amount of number theory are hashing, random number generation and error detection & correction.

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This is maybe too elementary --- very simple number theory is used in the classification of finite Markov Chains.

See for instance: Karlin & Taylor: A First Course in Stochastic Processes.

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