2020
DOI: 10.1002/adfm.202002122
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A Library of Late Transition Metal Alloy Dielectric Functions for Nanophotonic Applications

Abstract: Accurate complex dielectric functions are critical to accelerate the development of rationally designed metal alloy systems for nanophotonic applications, and to thereby unlock the potential of alloying for tailoring nanostructure optical properties. To date, however, accurate alloy dielectric functions are widely lacking. Here, a time‐dependent density‐functional theory computational framework is employed to compute a comprehensive binary alloy dielectric function library for the late transition metals most c… Show more

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Cited by 36 publications
(100 citation statements)
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“…[ 71 ] In fact, a very recent study has adopted this approach to establish a dielectric function library for binary alloys composed of the common coinage and noble metal constituents. [ 72 ] In this section, however, we concentrate on the modeling of ε from the semiclassical perspective, which helps to provide more intuitive and straightforward understanding of the alloy systems.…”
Section: Optical Properties Of Metal Alloysmentioning
confidence: 99%
“…[ 71 ] In fact, a very recent study has adopted this approach to establish a dielectric function library for binary alloys composed of the common coinage and noble metal constituents. [ 72 ] In this section, however, we concentrate on the modeling of ε from the semiclassical perspective, which helps to provide more intuitive and straightforward understanding of the alloy systems.…”
Section: Optical Properties Of Metal Alloysmentioning
confidence: 99%
“…Alloying in photonics is a promising route for obtaining materials properties and functionalities otherwise unachievable with single material-based structures [1][2][3][4] . Combining different chemical elements opens up avenues of possibilities to fine-tune the optical and electronic response of devices for a broad range of applications such as energy harvesting 5 , continuous-wave and pulsed lasing 3,6 , and non-linear optics 7 .…”
Section: Introductionmentioning
confidence: 99%
“…Combining different chemical elements opens up avenues of possibilities to fine-tune the optical and electronic response of devices for a broad range of applications such as energy harvesting 5 , continuous-wave and pulsed lasing 3,6 , and non-linear optics 7 . In the last decade, the rapid progress of the plasmonic field occurred due to the advance of new techniques of fabrication and characterization of pure metallic structures 4,8 . More recently, a change of paradigm driven by the maturing of nanofabrication methods and the systematic analysis of alloyed nanostructured systems [9][10][11] resulted in the rise of applications of this novel system as plasmonic tweezers 12 , hydrogen sensors 13 , photocatalystis 14 , and bio-sensors 15 .…”
Section: Introductionmentioning
confidence: 99%
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