Unlocking the Riemann Hypothesis: Novel Pathways from Dynamical Systems

Exploring Dynamical Systems and the Riemann Hypothesis

This article investigates potential research directions toward proving the Riemann Hypothesis (RH) using a novel approach based on dynamical systems theory. The analysis builds upon recent mathematical frameworks that reveal unexpected connections between seemingly disparate fields.

Framework 1: Connecting Exponential Sums to Zeta Function Zeros

The paper introduces exponential sums involving the von Mangoldt function, Λ(k), which plays a crucial role in the explicit formula for the distribution of prime numbers and the zeros of the Riemann zeta function, ζ(s). A key equation from the paper is:

∑_{0 ≤ k < gⁿ} Λ(k)f_n,A,d(k) = Ng^-|A|(g/φ(g))[1 + O(...)]

Proposed Theorem: Establish a theorem linking the growth rates of these sums to the distribution of non-trivial zeros of ζ(s). We hypothesize that specific bounds or properties of these sums directly influence the distribution and properties of these zeros. This could lead to new zero-free region estimates.

Framework 2: Uniform Distribution and Zeta Function Zeros

The paper also investigates sums involving fractional parts and their uniform distribution modulo 1. This is highly relevant to the vertical distribution of zeros in the critical strip of ζ(s).

∑_{1 ≤ q ≤ Q, (q,g)=1} ∑_{1 ≤ a ≤ q, (a,q)=1} g^|A||F_n,A,d(a/q)|

Proposed Theorem: Connect the magnitude and distribution of these sums with the density and spacing of zeros of ζ(s) along critical lines. This could yield new insights into zero-density estimates, a critical aspect of RH research.

Framework 3: Error Term Analysis and Zero Spacing

The detailed error term analysis in the paper offers a unique perspective. The error terms, such as O_g,c,ε(n^{6-α(1-b-(1+ε)(5b₁+3t))}log n), could provide crucial information.

Research Direction: Analyze the asymptotic behavior of these error terms and compare them to known bounds and estimates for the Riemann zeta function zeros. This could lead to tighter bounds on zero-free regions.

Novel Approach 1: g-adic Decomposition of Zeta Zeros

The paper's g-adic framework can potentially be extended to analyze the Riemann zeta function. We propose defining analogous functions for zeta zeros:

F_ζ(s) = Π_ρ (1 - g^s-ρ)

where ρ represents the non-trivial zeros of ζ(s). By employing the paper's techniques for bounding exponential sums, we can study the distribution properties of these functions.

Challenges: Extending the methods to complex-valued functions and developing new tools for infinite products are key challenges.

Novel Approach 2: Character Sums and L-functions

The paper's character sum estimates can be used to analyze the behavior of Dirichlet L-functions, which are closely related to the Riemann zeta function. We propose studying the relationships between:

∑_{χ mod q} |L(1/2 + it, χ)|

and the bounds for F_n,A,d from the paper. This could lead to new zero-density estimates for L-functions, offering a potential pathway to RH.

Tangential Connections: Fractal Geometry and Zeta Zeros

Investigate whether the fractal structures potentially encoded in the error terms and distribution functions F_n,A,d have analogs in the geometric distribution of zeta zeros on the critical line. Numerical simulations could be used to visualize and compare these potential fractal structures, searching for correlations.

Research Agenda

This research agenda requires several steps:

• Establish g-adic decomposition for ζ(s): Prove convergence properties, develop explicit formulas, and study behavior near the critical line.
• Extend exponential sum estimates: Adapt the paper's bounds to the complex domain and prove analogous results for ζ(s).
• Develop intermediate results: Derive g-adic approximation theorems, character sum bounds in the critical strip, and improved error term estimates for a modified explicit formula.

By systematically addressing these points, we can potentially make significant progress toward proving or disproving the Riemann Hypothesis.