# Towards broadband dynamic structuring of a complex plasmonic field

**Authors:** Shibiao Wei, Guangyuan Si, Michael Malek, Stuart K. Earl, Luping Du,, Shan Shan Kou, Xiaocong Yuan, and Jiao Lin

arXiv: 1702.04844 · 2017-02-17

## TL;DR

This paper presents a reconfigurable, wavelength-independent platform for tailoring complex 2D surface plasmon polariton fields, advancing nanophotonic applications by considering the coherent field as a whole rather than individual spots.

## Contribution

It introduces a novel design methodology for 2D SPP fields that accounts for coherence and constraints, applicable to other wave systems beyond plasmonics.

## Key findings

- Reconfigurable platform for 2D SPP fields
- Wavelength-independent design approach
- Revealed inherent constraints in coherent fields

## Abstract

The ability to tailor a coherent surface plasmon polariton (SPP) field is an important step towards a number of new opportunities for a broad range of nanophotonic applications such as sensing [1,2], nano-circuitry [3,4], optical data storage [5,6], super-resolution imaging [7,8], plasmonic tweezers [9,10] and in-plane communications [11]. Scanning a converging SPP spot or designing SPP profiles using an ensemble of spots have both been demonstrated previously [12-14]. SPPs, however, are normally excited by intense, coherent light sources-lasers. Hence, interference between adjacent spots is inevitable and will affect the overall SPP field distributions. Here we report a reconfigurable and wavelength-independent platform for generating a tailored 2D SPP field distribution by considering the coherent field as a whole rather than individual spots. The new perspective also enables us to reveal the inherent constraints implied in a 2D coherent field distribution. Our generic design methodology works not only for SPP waves but also for other two-dimensional wave systems like surface acoustic waves [15].

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Source: https://tomesphere.com/paper/1702.04844