Dielectric and optical properties of superlattices of epitaxially connected nanocrystals

Abstract: Colloidal semiconductor nanocrystals (NCs) are believed to strongly absorb resonant light; this property is key to ongoing applications of NCs as phosphor in light-emitting diodes (LEDs) for lighting, in displays, and photodetectors. However, it has been realized that NCs in a low dielectric medium suffer from a weak permeation of the electromagnetic field in the solid due to formation of depolarization fields, strongly reducing light absorption, as quantified by the local-field factor. For low-dimensional sem… Show more

“…Superlattices represent a distinct category of materials with periodic structures, potentially exhibiting unique properties such as dielectric, 1 optical, 1−4 magneto-optical, 5 electrical, 6 mechanical, 7 and gas-sensing characteristics. 8 Within the realm of nanoscale self-assembly, the investigation of nanopolyhedron-based superlattices has been a subject of comprehensive research, both experimentally and theoretically, spanning several decades.…”

“…Superlattices represent a distinct category of materials with periodic structures, potentially exhibiting unique properties such as dielectric, optical, − magneto-optical, electrical, mechanical, and gas-sensing characteristics . Within the realm of nanoscale self-assembly, the investigation of nanopolyhedron-based superlattices has been a subject of comprehensive research, both experimentally and theoretically, spanning several decades. − Prior research has predominantly centered on superlattices assembled using non-octahedral building blocks, , such as nanocubes, which typically adopt simple cubic structures. − However, employing nano-octahedra as the assembly building blocks presents a compelling deviation. , For instance, Zhu et al observed a fascinating monolayer arrangement comprising 70 nm gold nano-octahedra, while Gong et al confirmed the presence of simple hexagonal and monoclinic (reconstructed as triclinic in this work) superstructures of gold nano-octahedron self-assemblies via a scanning electron microscopy technique.…”

Randomly Layered Superstructure of In₂O₃ Truncated Nano-Octahedra and Its High-Pressure Behavior

“…Superlattices represent a distinct category of materials with periodic structures, potentially exhibiting unique properties such as dielectric, 1 optical, 1−4 magneto-optical, 5 electrical, 6 mechanical, 7 and gas-sensing characteristics. 8 Within the realm of nanoscale self-assembly, the investigation of nanopolyhedron-based superlattices has been a subject of comprehensive research, both experimentally and theoretically, spanning several decades.…”

“…Superlattices represent a distinct category of materials with periodic structures, potentially exhibiting unique properties such as dielectric, optical, − magneto-optical, electrical, mechanical, and gas-sensing characteristics . Within the realm of nanoscale self-assembly, the investigation of nanopolyhedron-based superlattices has been a subject of comprehensive research, both experimentally and theoretically, spanning several decades. − Prior research has predominantly centered on superlattices assembled using non-octahedral building blocks, , such as nanocubes, which typically adopt simple cubic structures. − However, employing nano-octahedra as the assembly building blocks presents a compelling deviation. , For instance, Zhu et al observed a fascinating monolayer arrangement comprising 70 nm gold nano-octahedra, while Gong et al confirmed the presence of simple hexagonal and monoclinic (reconstructed as triclinic in this work) superstructures of gold nano-octahedron self-assemblies via a scanning electron microscopy technique.…”

Randomly Layered Superstructure of In₂O₃ Truncated Nano-Octahedra and Its High-Pressure Behavior

Recent advances in PVP-assisted thermal treatment: Impact on nanostructure properties, potential applications, challenges, and future perspectives