Manifestations of chaos in billiards: the role of mixed curvature (2501.08839v2)

Abstract: The boundary of a billiard system plays a crucial role in shaping its dynamics, which may be integrable, mixed, or fully chaotic. When a boundary has varying curvature, it offers a unique setting to study the relation between classical chaos and quantum behaviour. In this study, we introduce two geometrically distinct billiards: a bean-shaped boundary and a peanut-shaped variant of Cassini ovals. These systems incorporate both focusing and defocusing walls with no neutral segments. Our study reveals a strong correlation between classical and quantum dynamics. Our analysis of billiard flow diagrams confirms sensitivity to initial conditions(ICs)- a defining feature of chaos. Poincar\'e maps further show the phase space intricately woven with regions of chaotic motion and stability islands. Moving to the quantum domain, we employ nearest-neighbour spacing distribution and level spacing ratio as statistical measures to characterise chaos. Early time saturation in spectral complexity also supports an ergodic hierarchy in these systems. We observe a striking quantum phenomenon, i.e. eigenfunction scarring. This work bridges geometric boundary effects, classical hyperbolicity, and quantum ergodicity, offering a framework to engineer chaos in confined systems.

• The paper demonstrates that mixed-curvature boundaries in bean and peanut-shaped billiards yield both regular and chaotic dynamics, analyzed through Lyapunov exponents and phase space trajectories.
• It reveals that quantum analyses exhibit pronounced eigenfunction scarring and level repulsion, aligning with GOE statistics and highlighting the interplay between classical chaos and quantum behavior.
• The study underscores potential applications of spectral complexity measures in optimizing quantum computing, optical design, and complex systems modeling.

Manifestations of Chaos in Billiards: The Role of Mixed Curvature

This paper investigates the impact of boundary curvature on the dynamics of billiard systems, focusing on billiards with mixed curvature, namely the bean-shaped and peanut-shaped billiards. These models incorporate both concave and convex boundaries, contributing to a complex interplay between regular and chaotic dynamical behaviors. While traditional investigations have concentrated on billiards with either fully integrable or chaotic dynamics, this paper presents a nuanced exploration into the dynamics of systems with mixed curvatures.

Classical Dynamics in Billiard Systems

Classically, the behavior of a particle within a billiard system is highly sensitive to initial conditions due to the configuration of the billiard boundary. The authors define a billiard trajectory as a series of linear segments determined by elastic collisions at the boundary. Each boundary of the billiard, whether convex, concave, or flat, contributes differently to the system’s dynamic behavior through mechanisms of focusing or defocusing particle trajectories.

In the provided analysis, the distinction between integrable and chaotic systems is made evident through the investigation of Lyapunov exponents, energy spectra, and phase space representations. The bean-shaped and peanut-shaped billiards exhibit a mixture of regular, periodic, and notably chaotic trajectories due to the presence of both positive and negative curvatures in their boundaries. This intricately crafted geometry facilitates the sustenance of classical chaos, as highlighted by the exponential divergence of nearby trajectories in phase space.

Quantum Analyses: Scarring and Spectral Complexity

The interplay between classical chaos and quantum mechanics is examined using eigenfunction analysis and statistical measures of energy levels. Notably, the paper highlights eigenfunction scarring—a phenomenon where quantum states localize along unstable classical periodic orbits. Such scarring is more pronounced in chaotic systems and is vividly observable in the setup of these mixed-curvature billiards. Additionally, super-scarred states, which do not correspond to any direct classical trajectory, further illustrate the quantum complexity inherent in these systems.

The paper employs Random Matrix Theory (RMT) to investigate nearest-neighbor spacing distributions (NNSDs) of the quantum states, contrasting the expected Poisson statistics for regular billiards with the Wigner-Dyson distribution observed in chaotic systems. This distinction is reinforced through the analysis of level spacing ratios, where chaotic systems show significant level repulsion as predicted by Gaussian Orthogonal Ensemble (GOE) statistics—a characteristic signature of quantum chaos.

Moreover, the paper introduces the concept of spectral complexity to measure the quantum complexity associated with billiard dynamics. Through spectral complexity, one can explore how quickly and in what manner the complexity saturates over time, providing insights into the qualitative nature of quantum chaotic systems. The temporal behavior of spectral complexity, particularly its earlier saturation in chaotic systems compared to integrable ones, underscores its utility as a diagnostic tool in quantum chaos studies.

Implications and Future Work

The exploration of billiard models with mixed curvatures illuminates critical aspects of both classical and quantum chaos. Chaotic billiards such as the bean and peanut models provide an enhanced understanding of how intricate boundary geometries influence both the chaotic dynamics and quantum signatures in systems, valuable for areas beyond theoretical physics, such as in optical devices' design and materials science.

The paper prompts further research into the analytical characterization of scarring and the development of systematic approaches to predict scarring in other dynamical systems. As the field progresses, investigations into the interplay of classical ergodic properties and their quantum analogs could pave the way for new computational and analytical techniques to manage quantum chaos in practical applications, such as quantum computing and complex systems modeling.