# A strictly ergodic, positive entropy subshift uniformly uncorrelated to   the Moebius function

**Authors:** Tomasz Downarowicz, Jacek Serafin

arXiv: 1902.04162 · 2019-02-13

## TL;DR

This paper constructs a strictly ergodic subshift with positive entropy that is uniformly uncorrelated to the M"obius function, advancing understanding of Sarnak's conjecture and the strong MOMO property.

## Contribution

It improves previous results by creating a strictly ergodic, positive entropy subshift that is uniformly uncorrelated to the M"obius function, demonstrating that strong MOMO is stronger than uniform uncorrelation.

## Key findings

- Constructed a strictly ergodic subshift with high entropy uncorrelated to M"obius.
- Showed uniform uncorrelation is achievable in strictly ergodic systems.
- Established that strong MOMO exceeds uniform uncorrelation in strength.

## Abstract

A recent result of Downarowicz and Serafin (DS) shows that there exist positive entropy subshifts satisfying the assertion of Sarnak's conjecture. More precisely, it is proved that if $y=(y_n)_{n\ge 1}$ is a bounded sequence with zero average along every infinite arithmetic progression (the M\"obius function is an example of such a \sq\ $y$) then for every $N\ge 2$ there exists a subshift $\Sigma$ over $N$ symbols, with entropy arbitrarily close to $\log N$, uncorrelated to $y$.   In the present note, we improve the result of (DS). First of all, we observe that the uncorrelation obtained in (DS) is \emph{uniform}, i.e., for any continuous function $f:\Sigma\to {\mathbb R}$ and every $\epsilon>0$ there exists $n_0$ such that for any $n\ge n_0$ and any $x\in\Sigma$ we have $$ \left|\frac1n\sum_{i=1}^{n}f(T^ix)\,y_i\right|<\epsilon. $$ More importantly, by a fine-tuned modification of the construction from (DS) we create a \emph{strictly ergodic} subshift, with all the desired properties of the example in (DS) (uniformly uncorrelated to $y$ and with entropy arbitrarily close to $\log N$).   The question about these two additional properties (uniformity of uncorrelation and strict ergodicity) has been posed by Mariusz Lemanczyk in the context of the so-called strong MOMO (M\"obius Orthogonality on Moving Orbits) property. Our result shows, among other things, that strong MOMO is essentially stronger than uniform uncorrelation, even for strictly ergodic systems.

## Full text

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## References

5 references — full list in the complete paper: https://tomesphere.com/paper/1902.04162/full.md

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Source: https://tomesphere.com/paper/1902.04162