Ju-Hyok Wi scite author profile

In two‐dimensional electrides, anionic electrons are spatially confined in interlayer regions with high density, comparable to metals, and they are highly mobile, just as free electrons, resembling hyperbolic metamaterials with metal‐dielectric multilayered structures. In this work, two‐dimensional electride materials MgONa and CaONa are proposed as good natural hyperbolic materials. By using the first‐principles calculations based on density functional theory (DFT), the electronic structures, stabilities, and optical properties of two‐dimensional electride materials XONa (X=Mg, Ca) are investigated. Our results show that they are stable in 1‐monolayer (1‐ML) structures as well as in bulk states. They exhibit hyperbolic dispersions from visible to near infrared spectral range with high qualities up to about 700, which is two orders‐of‐magnitude larger than the preceding bulk hyperbolic materials. Numerical results reveal that they exhibit negative refraction with low losses. Their high‐quality hyperbolic responses over a wide spectral range pave the way of broad photonic applications as natural hyperbolic materials.

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Negative Refraction in the Visible and Strong Plasmonic Resonances in Photonic Structures of the Electride Material Mg₂N

Kim

Choe

2020

ChemPhysChem

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Natural hyperbolic materials have recently attracted great attention due to their capability of supporting spatial mode frequency much higher than artificial metamaterials and the advantage that they do not require nanofabrication processes. For practical applications, however, hyperbolic bulk materials with lower optical losses in shorter wavelength range should be developed. This work presents the electronic structure and dielectric response of an electride Mg2N, revealing that this material exhibits hyperbolic responses with low optical loss in the visible and plasmonic responses with high‐quality in the near‐infrared range. Negative refraction in the red spectral range has been analytically and numerically demonstrated. In particular, nanoantenna structures of Mg2N generate strong plasmonic resonances in the near‐infrared and the intensity enhancement in the gap region is one order of magnitude higher compared with silver nanoantenna due to its much higher quality factor, which can find potential applications for nanoplasmonic purposes such as single molecule detections by surface‐enhanced hyper‐Raman spectroscopy and nonlinear wavelength generations at the nanoscale.

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First principles study on the structural, electronic, and transport properties of the Armchair Graphane, fluorographene, fluorographane/graphene heterostructure nanoribbons terminated by H and F atoms

Kim³

et al. 2019

Physica E: Low-dimensional Systems and Nanostructures

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Effects of single– and co– substitution of Ti and Fe on vacancy formation and dehydrogenation from MgH2 (110) surface: Ab initio study

Um²,

et al. 2019

International Journal of Hydrogen Energy

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Ju-Hyok Wi

Ab initio study on destabilizing mechanism of magnesium hydride by Ti and Fe co-doping

The Two‐Dimensional Electrides XONa (X=Mg, Ca) as Novel Natural Hyperbolic Materials

Negative Refraction in the Visible and Strong Plasmonic Resonances in Photonic Structures of the Electride Material Mg₂N

First principles study on the structural, electronic, and transport properties of the Armchair Graphane, fluorographene, fluorographane/graphene heterostructure nanoribbons terminated by H and F atoms

Effects of single– and co– substitution of Ti and Fe on vacancy formation and dehydrogenation from MgH2 (110) surface: Ab initio study

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Ju-Hyok Wi

Ab initio study on destabilizing mechanism of magnesium hydride by Ti and Fe co-doping

The Two‐Dimensional Electrides XONa (X=Mg, Ca) as Novel Natural Hyperbolic Materials

Negative Refraction in the Visible and Strong Plasmonic Resonances in Photonic Structures of the Electride Material Mg2N

First principles study on the structural, electronic, and transport properties of the Armchair Graphane, fluorographene, fluorographane/graphene heterostructure nanoribbons terminated by H and F atoms

Effects of single– and co– substitution of Ti and Fe on vacancy formation and dehydrogenation from MgH2 (110) surface: Ab initio study

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Product

Resources

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Negative Refraction in the Visible and Strong Plasmonic Resonances in Photonic Structures of the Electride Material Mg₂N