# Chiral Balls: Knotted Structures with Both Chirality and   Three-dimensional Rotational Symmetry

**Authors:** Wending Mai, Chunxu Mao, Lei Kang, Yifan Chen, Jun Hu, Douglas H., Werner

arXiv: 1904.05750 · 2019-08-12

## TL;DR

This paper introduces chiral balls, knotted structures with both chirality and 3-D rotational symmetry, exhibiting unique isotropic circularly polarized scattering properties with potential broad scientific impact.

## Contribution

The paper reports the discovery of chiral balls, a new class of knotted structures with combined chirality and 3-D symmetry, and analyzes their novel electromagnetic scattering behavior.

## Key findings

- Chiral balls exhibit isotropic circularly polarized scattering.
- They possess both chirality and 3-D rotational symmetry.
- The structures have potential applications in electromagnetics and optics.

## Abstract

Knots have been put forward to explain various physical phenomena because of their topological stability. Nevertheless, few works have reported on the exotic symmetry properties that certain knots possess. Here we reveal an exceptional form of symmetry for a family of knots that are both chiral and three-dimensional (3-D) rotationally symmetric about every axis of a standard Cartesian coordinate system. We call these unique knotted structures chiral balls. To demonstrate the unprecedented physical characteristics exhibited by these unique structures, we study the electromagnetic scattering properties of a representative conductive chiral ball. In particular, a characteristic mode analysis is performed to investigate the intrinsic scattering properties of this chiral ball. With both chirality and 3-D rotational symmetry, the chiral ball is shown to exhibit an extraordinary isotropic circularly polarized scattering property, which has not been previously reported for any known electromagnetic structures. Because of their unique properties, chiral balls are expected to not only have a profound impact on the fields of electromagnetics and optics but also far beyond.

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Source: https://tomesphere.com/paper/1904.05750