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1 - He-Ne laser speckle
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2 - Interference fringes in a soap bubble
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3 - Fractal electron tree or Lichtenberg figure

About us

We are a theoretical research group at the School of Electrical and Electronic Engineering and the Institute for Digital Molecular Analytics and Science at Nanyang Technological University, Singapore. The group is lead by Assistant Professor Matthew R. Foreman.

Our research focuses on optical and plasmonic sensing, polarisation sensitive imaging, disordered media and electromagnetic theory. More information on some of our past and present projects can be found by visiting our Research pages.

Recent news

New arXiv preprint

28 Oct 2024: We're pleased to share our most recent work on Generalized Wigner-Smith analysis of resonance perturbations in low Q non-Hermitian systems which has just gone live on arXiv. This is a follow on work from our earlier generalised Wigner Smith operator based perturbation theory article and presents a number of key generalisations to broaden the applicability and validity of our theory.

New Research Associate - Tanmay Bhowmik

28 Oct 2024: OTG welcomes its latest addition - Tanmay Bhowmik. He joins our efforts at IDMxS and will deploy his expertise in simulating plasmonic and nanophotonic devices to help us design improved molecular analytic platforms and nanoparticle assays.

New arXiv preprint

22 Aug 2024: We just posted some exciting new results from the Optical Theory Group to arXiv. Specifically, we demonstrate a novel perturbation theory based on generalised Wigner-Smith operators. This provides a powerful tool for describing resonance shifts and broadening in open non-Hermitian systems. We also have another work in the pipeline to expand the domain of validy of the presented theory, so watch this space for more updates.

Recent publications

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Abstract : Perturbing resonant systems causes shifts in their associated scattering poles in the complex plane. In a previous study [arXiv: 2408.11360], we demonstrated that these shifts can be calculated numerically by analyzing the residue of a generalized Wigner-Smith operator associated with the perturbation parameter. In this work, we extend this approach by connecting the Wigner-Smith formalism with results from standard electromagnetic perturbation theory applicable to open systems with resonances of arbitrary quality factors. We further demonstrate the utility of the method through several numerical examples, including the inverse design of a multi-layered nanoresonator sensor and an analysis of the enhanced sensitivity of scattering zeros to perturbations.

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Abstract : Resonances of open non-Hermitian systems are associated with the poles of the system scattering matrix. Perturbations of the system cause these poles to shift in the complex frequency plane. In this work, we introduce a novel method for calculating shifts in scattering matrix poles using generalized Wigner-Smith operators. We link our method to traditional cavity perturbation theory and validate its effectiveness through application to complex photonic networks. Our findings underscore the versatility of generalized Wigner-Smith operators for analyzing a broad spectrum of resonant systems and provides new insight into resonant properties of non-Hermitian systems.

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N. Byrnes, G. R. W. Greaves and M. R. Foreman, "Bootstrapping cascaded random matrix models: Correlations in permutations of matrix products" Phys. Rev. E 110, 015308 (2024).

Abstract : Random matrix theory is a useful tool in the study of the physics of multiple scattering systems, often striking a balance between computation speed and physical rigour. Propagation of waves through thick disordered media, as arises in for example optical scattering or electron transport, typically necessitates cascading of multiple random matrices drawn from an underlying ensemble for thin media, greatly increasing computational burden. Here we propose a dual pool based bootstrapping approach to speed up statistical studies of scattering in thick random media. We examine how potential matrix reuse in this approach can impact statistical estimates of population averages. Specifically, we discuss how both bias and additional variance in the sample mean estimator are introduced through bootstrapping. In the diffusive scattering regime, the extra estimator variance is shown to originate from samples in which cascaded transfer matrices are permuted matrix products. Through analysis of the combinatorics and cycle structure of permutations we quantify the resulting correlations. Proofs of several analytic formulae enumerating the frequency with which correlations of different strengths occur are derived. Extension to the ballistic regime is briefly considered.

Funding

Our research is supported by generous funding from:

Microsoft Research
IDMxS
NTU
Ministry of Education