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Ben Green (University of Cambridge), Bryna Kra (Northwestern University), Emmanuel Lesigne (University of Tours), Anthony Quas (University of Victoria), Mate Wierdl (University of Memphis)
Significantly modern operate in ergodic idea has been motivated by interactions with combinatorics and with number theory. A specific is instance is Szemerédi's Theorem,
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Furstenberg's proof uncovered the connection between combinatorial results and ergodic theory,
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The recent result of Green and Tao on arbitrarily long arithmetic progressions in the set of primes immediately attracted the attention of ergodic theorists. The Green-Tao proof, similar to Furstenberg's proofs, is based on a philosophy used in ergodic idea since Riesz's proof of the Mean Ergodic Theorem: prove a structure theorem, showing that a given object can be decomposed into "structured" and "negligible" parts. However,
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One aim of the proposed program is to understand the meaning of these current results for ergodic principle. As the history of Szemerédi's Theorem shows, such an understanding benefits both ergodic principle and other fields, such as probability, combinatorics, quantity concept and harmonic analysis.
A difficulty facing researchers in this area is the need to be fluent in several felds of mathematics: quantity concept, ergodic idea,
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For information how to apply please go to: Member Application
Workshop(s):
Broader Connections: Ergodic Concept and Additive Combinatorics
Introduction to Ergodic Principle and Additive Combinatorics