Abstract: A method for preparing an erbium (Er)- or erbium oxygen (Er/O)-doped silicon-based luminescent material emitting a communication band at room temperature. The method comprising the following steps: (a) doping a single crystalline silicon wafer with erbium ion implantation or co-doping the single crystalline silicon wafer with erbium ion and oxygen ion implantation simultaneously to obtain an Er- or Er/O-doped silicon wafer, wherein the single crystalline silicon wafer is a silicon wafer with a germanium epitaxial layer, or an SOI silicon wafer with silicon on an insulating layer or other silicon-based wafers; and (b) subjecting the Er- or Er/O-doped silicon wafer to a deep-cooling annealing treatment, the deep-cooling annealing treatment includes a temperature increasing process and a rapid cooling process.

Abstract: A method for preparing an erbium (Er)- or erbium oxygen (Er/O)-doped silicon-based luminescent material emitting a communication band at room temperature. The method comprising the following steps: (a) doping a single crystalline silicon wafer with erbium ion implantation or co-doping the single crystalline silicon wafer with erbium ion and oxygen ion implantation simultaneously to obtain an Er- or Er/O-doped silicon wafer, wherein the single crystalline silicon wafer is a silicon wafer with a germanium epitaxial layer, or an SOI silicon wafer with silicon on an insulating layer or other silicon-based wafers; and (b) subjecting the Er- or Er/O-doped silicon wafer to a deep-cooling annealing treatment, the deep-cooling annealing treatment includes a temperature increasing process and a rapid cooling process.

Abstract: A nanowire array is described herein. The nanowire array comprises a substrate and a plurality of nanowires extending essentially vertically from the substrate; wherein: each of the nanowires has uniform chemical along its entire length; a refractive index of the nanowires is at least two times of a refractive index of a cladding of the nanowires. This nanowire array is useful as a photodetector, a submicron color filter, a static color display or a dynamic color display.

Abstract: An optical apparatus, including an optical filter comprising an array of nanowires oriented perpendicular to a light incidence surface of the filter, wherein the optical filter transmits light at a first wavelength that is incident on the incidence surface, wherein the first wavelength is based on a cross-sectional shape of the nanowires. The nanowires are created using a single lithography step. An imaging device and a method of fabricating the same, the device including an array of nanowires formed on a substrate, wherein at least one nanowire in the array of nanowires includes a photoelectric element to produce a photocurrent based, at least in part, on incident photons absorbed by the at least one nanowire.

Abstract: A nanowire array is described herein. The nanowire array comprises a substrate and a plurality of nanowires extending essentially vertically from the substrate; wherein: each of the nanowires has uniform chemical along its entire length; a refractive index of the nanowires is at least two times of a refractive index of a cladding of the nanowires. This nanowire array is useful as a photodetector, a submicron color filter, a static color display or a dynamic color display.

Abstract: A nanowire array is described herein. The nanowire array comprises a substrate and a plurality of nanowires extending essentially vertically from the substrate; wherein: each of the nanowires has uniform chemical along its entire length; a refractive index of the nanowires is at least two times of a refractive index of a cladding of the nanowires. This nanowire array is useful as a photodetector, a submicron color filter, a static color display or a dynamic color display.

Abstract: Disclosed are atomically precise nanoribbons formed by gradient-driven catalytic etching of crystalline substrates to produce edges formed along specific crystallographic axes by thermally-activated particles. Also provided are related methods for fabrication of these nanoribbon structures. Further provided are devices and related methods for power generation and for detection of specific targets using the disclosed structures.

Abstract: A nanowire array is described herein. The nanowire array comprises a substrate and a plurality of nanowires extending essentially vertically from the substrate; wherein: each of the nanowires has uniform chemical along its entire length; a refractive index of the nanowires is at least two times of a refractive index of a cladding of the nanowires. This nanowire array is useful as a photodetector, a submicron color filter, a static color display or a dynamic color display.

Abstract: Embodiments relate to methods and devices comprising an optical pipe comprising a core and a cladding. An embodiment includes obtaining a substrate comprising a photodiode and a first protective layer, the first protective layer having a predetermined thickness and growing a nanowire having a length L on the photodiode, wherein the length L is greater than the predetermined thickness of the protective layer. Another embodiment includes (1) obtaining a substrate comprising a photodiode and a protective layer, (2) fabricating a nanowire light pipe on the photodiode, the light pipe comprising a nanowire core and a cladding; and (3) coating the substrate and the nanowire light pipe with a protective coating.