# Momentum-resolved Electron Energy Loss Spectroscopy for Mapping the   Photonic Density of States

**Authors:** Prashant Shekhar, Marek Malac, Vaibhav Gaind, Neda Dalili, Al Meldrum,, Zubin Jacob

arXiv: 1702.00491 · 2017-04-10

## TL;DR

This paper demonstrates how momentum-resolved electron energy loss spectroscopy (q-EELS) can effectively map the photonic density of states in nanoscale structures, revealing high-momentum photonic phenomena beyond the light cone.

## Contribution

It introduces the use of q-EELS in a transmission electron microscope to explore and map the momentum-dependent optical response of plasmonic thin films, including high-q modes.

## Key findings

- q-EELS maps agree with theoretical simulations and q-PDOS dispersion.
- Differences between q-EELS and q-PDOS are significant in finite structures.
- q-EELS can be used to study high-q phenomena like hyperbolic polaritons.

## Abstract

Strong nanoscale light-matter interaction is often accompanied by ultra-confined photonic modes and large momentum polaritons existing far beyond the light cone. A direct probe of such phenomena is difficult due to the momentum mismatch of these modes with free space light however, fast electron probes can reveal the fundamental quantum and spatially dispersive behavior of these excitations. Here, we use momentum-resolved electron energy loss spectroscopy (q-EELS) in a transmission electron microscope to explore the optical response of plasmonic thin films including momentum transfer up to wavevectors (q) significantly exceeding the light line wave vector. We show close agreement between experimental q-EELS maps, theoretical simulations of fast electrons passing through thin films and the momentum-resolved photonic density of states (q-PDOS) dispersion. Although a direct link between q-EELS and the q-PDOS exists for an infinite medium, here we show fundamental differences between q-EELS measurements and the q-PDOS that must be taken into consideration for realistic finite structures with no translational invariance along the direction of electron motion. Our work paves the way for using q-EELS as the preeminent tool for mapping the q-PDOS of exotic phenomena with large momenta (high-q) such as hyperbolic polaritons and spatially-dispersive plasmons.

## Full text

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## Figures

4 figures with captions in the complete paper: https://tomesphere.com/paper/1702.00491/full.md

## References

40 references — full list in the complete paper: https://tomesphere.com/paper/1702.00491/full.md

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Source: https://tomesphere.com/paper/1702.00491