Hyperuniform disordered distribution metasurface for scattering reduction

Zhang, Haoyang; Cheng, Qiao; Chu, Hongchen; Christogeorgos, Orestis; Wu, Wen; Hao, Yang

doi:10.1063/5.0041911

Cited by 26 publications

(19 citation statements)

References 37 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Due to the interaction between an electromagnetic (EM) wave and metasurfaces in some specific geometrical arrangements, metasurfaces can exhibit remarkable electromagnetic wave responses that have attracted great interests [1][2][3][4]. Metasurfaces have served as an important technology in many applications such as heat transforming [5], cloaking [6,7], hologram [8], conversion [9], absorption [10,11], scattering reduction [12], polarization [13][14][15], transmission [16], color [17,18], metalense [14,15], programmable metasurfaces [19][20][21], and many others [22][23][24][25]. These applications are made possible by the rapid advancement in micro-and even nano-fabrication technologies and computational modeling over the past decades.…”

Section: Introductionmentioning

confidence: 99%

SUTD-PRCM Dataset and Neural Architecture Search Approach for Complex Metasurface Design

Zhang¹,

Ang²,

Li³

et al. 2022

Preprint

View full text Add to dashboard Cite

Section: Introductionmentioning

confidence: 99%

SUTD-PRCM Dataset and Neural Architecture Search Approach for Complex Metasurface Design

Zhang¹,

Ang²,

Li³

et al. 2022

Preprint

View full text Add to dashboard Cite

“…The large-R behavior of σ 2 V (R) is at the heart of the hyperuniformity concept. Hyperuniform two-phase media are characterized by an anomalous suppression of volume-fraction fluctuations relative to garden-variety disordered media [16,17] and can be endowed with novel properties [21,22,23,17,24,25,26,13,27,28,29,30,31,32,33,34,35]. Specifically, a hyperuniform two-phase system is one in which σ 2 V (R) decays faster than R −d in the large-R regime [16,17], i.e., lim…”

Section: Introductionmentioning

confidence: 99%

Local Order Metrics for Two-Phase Media Across Length Scales

Torquato,

Skolnick,

Kim

2022

Preprint

View full text Add to dashboard Cite

The capacity to devise order metrics for microstructures of multiphase heterogeneous media is a highly challenging task, given the richness of the possible geometries and topologies of the phases that can arise. This investigation initiates a program to formulate order metrics to characterize the degree of order/disorder of the microstructures of two-phase media in d-dimensional Euclidean space R d across length scales. In particular, we propose the use of the local volume-fraction variance σ 2V (R) associated with a spherical window of radius R as an order metric. We determine σ 2 V (R) as a function of R for 22 different models across the first three space dimensions, including both hyperuniform and nonhyperuniform systems with varying degrees of short-and long-range order. We find that the local volume-fraction variance as well as asymptotic coefficients and integral measures derived from it provide reasonably robust and sensitive order metrics to categorize disordered and ordered two-phase media across all length scales.

show abstract

“…Hyperuniformity is an emerging field, playing vital roles in a number of fundamental and applied contexts, including glass formation [19,20], jamming [21][22][23][24][25], rigidity [26,27], bandgap structures [28][29][30], biology [31,32], localization of waves and excitations [33][34][35], self-organization [36][37][38], fluid dynamics [39,40], quantum systems [41][42][43][44][45], random matrices [43,46,47] and pure mathematics [48][49][50][51][52]. Because disordered hyperuniform two-phase media are states of matter that lie between a crystal and a typical liquid, they can be endowed with novel properties [12,18,[53][54][55][56][57][58][59][60][61][62][63]…”

Section: Introductionmentioning

confidence: 99%

Dynamic Measure of Hyperuniformity and Nonhyperuniformity in Heterogeneous Media via the Diffusion Spreadability

Wang,

Torquato

2021

Preprint

View full text Add to dashboard Cite

Time-dependent interphase diffusion processes in multiphase heterogeneous media arise ubiquitously in physics, chemistry and biology. Examples of heterogeneous media include composites, geological media, gels, foams and cell aggregates. The recently developed concept of spreadability, S(t), provides a direct link between time-dependent diffusive transport and the microstructure of two-phase media across length scales [Torquato, S., Phys. Rev. E., 104 054102 (2021)]. To investigate the capability of S(t) to probe microstructures of real heterogeneous media, we explicitly compute S(t) for well-known two-dimensional and three-dimensional idealized model structures that span across nonhyperuniform and hyperuniform classes. Among the former class, we study fully penetrable spheres and equilibrium hard spheres, and in the latter class, we examine sphere packings derived from "perfect glasses", uniformly randomized lattices (URL), disordered stealthy hyperuniform point processes and Bravais lattices. Hyperuniform media are characterized by an anomalous suppression of volume fraction fluctuations at large length scales compared to that of any nonhyperuniform medium. We further confirm that the small-, intermediate-and long-time behaviors of S(t) sensitively capture the small-, intermediate-and large-scale characteristics of the models. In instances in which the spectral density χV (k) has a power-law form B|k| α in the limit |k| → 0, the long-time spreadability provides a simple means to extract the value of the coefficients α and B that is robust against noise in χV (k) at small wavenumbers. For typical nonhyperuniform media, the intermediate-time spreadability is slower for models with larger values of the coefficient B = χV (0). Interestingly, the excess spreadability S(∞) − S(t) for URL packings has nearly exponential decay at small to intermediate t, but transforms to a power-law decay at large t, and the time for this transition has a logarithmic divergence in the limit of vanishing lattice perturbation. Our study of the aforementioned models enables us to devise an algorithm that efficiently and accurately extracts large-scale behaviors from diffusion data alone. Lessons learned from such analyses of our models are used to determine accurately the large-scale structural characteristics of a sample Fontainebleau sandstone, which we show is nonhyperuniform. Our study demonstrates the practical applicability of the diffusion spreadability to extract crucial microstructural information from real data across length scales and provides a basis for the inverse design of materials with desirable time-dependent diffusion properties.

show abstract

Hyperuniform disordered distribution metasurface for scattering reduction

Cited by 26 publications

References 37 publications

SUTD-PRCM Dataset and Neural Architecture Search Approach for Complex Metasurface Design

SUTD-PRCM Dataset and Neural Architecture Search Approach for Complex Metasurface Design

Local Order Metrics for Two-Phase Media Across Length Scales

Dynamic Measure of Hyperuniformity and Nonhyperuniformity in Heterogeneous Media via the Diffusion Spreadability

Contact Info

Product

Resources

About