Your search keyword '"Ni, Xuan"' showing total 3 results

1. Transient chaos in optical metamaterials.

Author

Ni, Xuan and Lai, Ying-Cheng

Subjects

*OPTICAL materials, *METAMATERIALS, *REFRACTIVE index, *ELECTROMAGNETISM, *PERTURBATION theory, *MAXWELL equations, *GENERAL relativity (Physics), *CHAOS theory

Abstract

We investigate the dynamics of light rays in two classes of optical metamaterial systems: (1) time-dependent system with a volcano-shaped, inhomogeneous and isotropic refractive-index distribution, subject to external electromagnetic perturbations and (2) time-independent system consisting of three overlapping or non-overlapping refractive-index distributions. Utilizing a mechanical-optical analogy and coordinate transformation, the wave-propagation problem governed by the Maxwell's equations can be modeled by a set of ordinary differential equations for light rays. We find that transient chaotic dynamics, hyperbolic or nonhyperbolic, are common in optical metamaterial systems. Due to the analogy between light-ray dynamics in metamaterials and the motion of light in matter as described by general relativity, our results reinforce the recent idea that chaos in gravitational systems can be observed and studied in laboratory experiments. [ABSTRACT FROM AUTHOR]

Published

2011

2. Basins of coexistence and extinction in spatially extended ecosystems of cyclically competing species.

Author

Ni, Xuan, Yang, Rui, Wang, Wen-Xu, Lai, Ying-Cheng, and Grebogi, Celso

Subjects

*GEOLOGICAL basins, *BIOTIC communities, *BIOLOGICAL extinction, *COEXISTENCE of species, *ROCK-paper-scissors (Game), *COMPETITION (Biology), *SPECIES, *STOCHASTIC analysis

Abstract

Microscopic models based on evolutionary games on spatially extended scales have recently been developed to address the fundamental issue of species coexistence. In this pursuit almost all existing works focus on the relevant dynamical behaviors originated from a single but physically reasonable initial condition. To gain comprehensive and global insights into the dynamics of coexistence, here we explore the basins of coexistence and extinction and investigate how they evolve as a basic parameter of the system is varied. Our model is cyclic competitions among three species as described by the classical rock-paper-scissors game, and we consider both discrete lattice and continuous space, incorporating species mobility and intraspecific competitions. Our results reveal that, for all cases considered, a basin of coexistence always emerges and persists in a substantial part of the parameter space, indicating that coexistence is a robust phenomenon. Factors such as intraspecific competition can, in fact, promote coexistence by facilitating the emergence of the coexistence basin. In addition, we find that the extinction basins can exhibit quite complex structures in terms of the convergence time toward the final state for different initial conditions. We have also developed models based on partial differential equations, which yield basin structures that are in good agreement with those from microscopic stochastic simulations. To understand the origin and emergence of the observed complicated basin structures is challenging at the present due to the extremely high dimensional nature of the underlying dynamical system. [ABSTRACT FROM AUTHOR]

Published

2010

3. Emergence of scaling associated with complex branched wave structures in optical medium.

Author

Ni, Xuan, Lai, Ying-Cheng, and Wang, Wen-Xu

Subjects

*THEORY of wave motion, *MICROWAVES, *GAUSSIAN processes, *EXISTENCE theorems, *DISTRIBUTION (Probability theory), *SCATTERING (Physics)

Abstract

Branched wave structures, an unconventional wave propagation pattern, can arise in random media. Experimental evidence has accumulated, revealing the occurrence of these waves in systems ranging from microwave and optical systems to solid-state devices. Experiments have also established the universal feature that the wave-intensity statistics deviate from Gaussian and typically possess a long-tail distribution, implying the existence of spatially localized regions with extraordinarily high intensity concentration ('hot' spots). Despite previous efforts, the origin of branched wave pattern is currently an issue of debate. Recently, we proposed a 'minimal' model of wave propagation and scattering in optical media, taking into account the essential physics for generating robust branched flows: (1) a finite-size medium for linear wave propagation and (2) random scatterers whose refractive indices deviate continuously from that of the background medium. Here we provide extensive numerical evidence and a comprehensive analytic treatment of the scaling behavior to establish that branched wave patterns can emerge as a general phenomenon in wide parameter regime in between the weak-scattering limit and Anderson localization. The basic physical mechanisms to form branched waves are breakup of waves by a single scatterer and constructive interference of broken waves from multiple scatterers. Despite simplicity of our model, analysis of the scattering field naturally yields an algebraic (power-law) statistic in the high wave-intensity distribution, indicating that our model is able to capture the generic physical origin of these special wave patterns. The insights so obtained can be used to better understand the origin of complex extreme wave patterns, whose occurrences can have significant impact on the performance of the underlying physical systems or devices. [ABSTRACT FROM AUTHOR]

Published

2012