2020
DOI: 10.1021/acsphotonics.9b01368
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Beyond Noble Metals: High Q-Factor Aluminum Nanoplasmonics

Abstract: Aluminum, with its distinctively favorable dielectric characteristics down to deep ultraviolet (UV) regime, has recently emerged as a broad-band and low-cost alternative to noble metals. However, low Q-factor resonances (Q ∼ 2−4), offered by Al nanostructures, pose a fundamental bottleneck for many practical applications. Here, we show that it is possible to realize Al-nanoantenna with remarkably large extinction cross sections and strong resonance characteristics surpassing those of their noble metal counterp… Show more

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Cited by 52 publications
(47 citation statements)
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“…Traditional trial-and-error-based design approaches often require computationally expensive and timeconsuming three-dimensional rigorous electromagnetic simulations of tens to hundreds of candidate structures [121,122]. In contrast, we showed that our space mapping-based inverse design technique enables ultrafast and accurate retrieval of the fittest sets of structural PNA parameters, yielding the desired optical characteristics with a minimal number of high-fidelity and computationally expensive simulations [92]. Our inverse design approach establishes a one-to-one mapping scheme [123,124] enabling effective approximation of time-consuming finite difference time domain (FDTD) simulations using an analytical coupled dipole approximation (CDA) model that is not resource hungry.…”
Section: High Q-factor Broadband Plasmonic Nanoantennasmentioning
confidence: 87%
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“…Traditional trial-and-error-based design approaches often require computationally expensive and timeconsuming three-dimensional rigorous electromagnetic simulations of tens to hundreds of candidate structures [121,122]. In contrast, we showed that our space mapping-based inverse design technique enables ultrafast and accurate retrieval of the fittest sets of structural PNA parameters, yielding the desired optical characteristics with a minimal number of high-fidelity and computationally expensive simulations [92]. Our inverse design approach establishes a one-to-one mapping scheme [123,124] enabling effective approximation of time-consuming finite difference time domain (FDTD) simulations using an analytical coupled dipole approximation (CDA) model that is not resource hungry.…”
Section: High Q-factor Broadband Plasmonic Nanoantennasmentioning
confidence: 87%
“…The latest advances in nanoscale fabrication and nanophotonic characterization techniques, as well as powerful electromagnetic simulation methods, have enabled scientists and engineers to understand and harness plasmonic excitations in metallic PNAs with high efficiencies [14,31,75,76]. By employing these well-established toolsets, sophisticated devices can be readily designed with desired functionality through rigorous parametric optimization techniques [92,93]. For example, a well-engineered array of PNAs can support long-lived and high quality (Q)-factor optical resonances and high field enhancements over a broad spectral range down to deep UV regime.…”
Section: Metallic Plasmonic Nanoantennasmentioning
confidence: 99%
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