An optoelectronic device and a method of manufacturing the same. The device comprising: a multi-layered optically active stack; an input waveguide, arranged to guide light into the stack; an output waveguide, arranged to guide light out of the stack; and anti-reflective coatings, located between both the input waveguide and the stack and the stack and the output waveguide; wherein the input waveguide and output waveguide are formed of silicon nitride.

An optoelectronic device. The optoelectronic device operable to provide a PAM-N modulated output, the device comprising: M optical modulators, M being an integer greater than 1, the M optical modulators being arranged in a cascade, the device being configured to operate in N distinct transmittance states, as a PAM-N modulator, wherein, in each transmittance state of the N distinct transmittance states, each of the M optical modulators has applied to it a respective control voltage equal to one of: a first voltage or a second voltage. One or more of the modulators may include a substrate; a crystalline cladding layer, on top of the substrate; and an optically active region, above the crystalline cladding layer. The crystalline cladding layer may have a refractive index which is less than a refractive index of the optically active region.

A method of fabricating an optoelectronic component within a silicon-on-insulator substrate, the method comprising: providing a silicon-on-insulator (SOI) substrate, the SOI substrate comprising a silicon base layer, a buried oxide (BOX) layer on top of the base layer, and a silicon device layer on top of the BOX layer; etching a first cavity region into the SOI substrate and etching a second cavity region into the SOI substrate, the first cavity region having a first depth and the second cavity region having a second depth, the second depth being greater than the first depth; depositing a multistack epi layer into the first and the second cavity regions simultaneously, the multistack epi layer comprising a first multistack portion comprising a first active region and a second multistack portion comprising a second active region.

Disclosed is a quantum-confined Stark effect (QCSE) modulator. In the modulator, a first doped semiconductor region has a first type conductivity, is at the bottom of a trench in a dielectric layer and is immediately adjacent to a semiconductor layer. An MQW region is in the trench on the first doped semiconductor region and at least upper segments of sidewalls of the MQW region are angled away from adjacent sidewalls of the trench such that there are spaces between the MQW region and the dielectric layer. Dielectric spacers fill the spaces. A second doped semiconductor region has a second type conductivity, is on top of the MQW region and optionally extends laterally onto the tops of the dielectric spacers. The spacers prevent shorting of the doped semiconductor regions. Also disclosed are embodiments of a photonics structure including the modulator and of methods for forming the modulator and the photonics structure.

An optoelectronic device and an array comprising a plurality of the same. The device(s) comprising: an optically active region with an electrode arrangement for applying an electric field across the optically active region; a first curved waveguide, arranged to guide light into the optically active region; and a second curved waveguide, arranged to guide light out of the optically active region; wherein the first curved waveguide and the second curved waveguide are formed of a material having a different band-gap from a band-gap of the optically active region, and wherein the overall guided path formed by the first curved waveguide, the optically active region and the second curved waveguide is U-shaped.

Disclosed are structures as well as methods of manufacture and operation of integrated optoelectronic devices that facilitate directly heating the diode or waveguide structures to regulate a temperature of the device while allowing electrical contacts to be placed close to the device to reduce the electrical resistance. Embodiments include, in particular, heterogeneous electro-absorption modulators that include a compound-semiconductor diode structure placed above a waveguide formed in the device layer of an SOI substrate.

A silicon based electro-optically active device and method of producing the same. The silicon based electro-optically active device comprising: a silicon-on-insulator (SOI) waveguide; an electro-optically active waveguide including an electro-optically active stack within a cavity of the SOI waveguide; and a lined channel between the electro-optically active stack and the SOI waveguide, the lined channel comprising a liner; wherein the lined channel is filled with a filling material with a refractive index similar to that of a material forming a sidewall of the cavity, to thereby form a bridge-waveguide in the channel between the SOI waveguide and the electro-optically active stack.

A method for manufacturing a semiconductor optical device includes the steps of forming a first semiconductor layer on a substrate; forming a mask on the first semiconductor layer; forming a first mesa from the first semiconductor layer using the mask; forming an embedding layer on a portion of the first semiconductor layer that is exposed from the mask such that the first mesa is embedded in the embedding layer; and forming a second mesa from the first mesa.

A silicon based electro-optically active device and method of production thereof. The device comprising: a silicon-on-insulator (SOI) layer; an electro-optically active stack, disposed on top of the SOI layer: a first epitaxially grown structure comprising a first passive waveguide and a second epitaxially grown structure comprising a second passive waveguide, the first and second passive waveguides being disposed adjacent to respective sides of the electro-optically active stack, wherein the first and second passive waveguides are configured to edge couple light from the first passive waveguide into the electro-optically active stack and from the electro-optically active stack into the second passive waveguide; and an evanescent coupling structure, for evanescently coupling light between the SOI layer and the first and second passive waveguides.

A semiconductor device includes an electrode which is arranged on an organic material with an insulation film interposed therebetween and which does not easily peel away from the organic material along with the insulation film. An insulation film in a region including pad portions of a phase shift electrode and a modulation electrode has openings at the centers of the pad portions of the phase shift electrode and the modulation electrode, the edge portions of which are formed on the phase shift electrode and the modulation electrode. In this way, the adjoining edges of the phase shift electrode and modulation electrode and the insulation film are all covered by the insulation film so as not to be exposed to the atmosphere. By covering the cracks that occur in the insulation film in the production process with the insulation film made of SiO.sub.2, SiN.sub.x, SiON.sub.x or the like, an organic solvent such as acetone or ethanol used in the process can be prevented from seeping in between the insulation film and the organic material through the cracks in the insulation film.