A vertical cavity surface emitting laser element includes a first light reflecting film, a nitride semiconductor layered body, a p-electrode and a second light reflecting film. The nitride semiconductor layered body includes an n-side semiconductor layer disposed on the first light reflecting film, an active layer disposed on the n-side semiconductor layer, and a p-side semiconductor layer disposed on the active layer. The p-side semiconductor layer includes a protrusion and a surface around the protrusion. The p-electrode is in contact with an upper surface of the protrusion, and extends to the surface around the protrusion. The p-electrode is light-transmissive. The second light reflecting film is disposed on the p-electrode. A height of the protrusion as measured from the surface around the protrusion is smaller than a thickness of the p-electrode.

A method of forming a flip chip backside Vertical Cavity Surface Emitting Laser (VCSEL) package comprising: forming a VCSEL pillar array; applying a dielectric layer to the VCSEL pillar array, the dielectric layer filling trenches in between pillars forming the VCSEL pillar array and covering the pillars; planarizing the VCSEL pillar array to remove the dielectric layer covering the pillars exposing a metal layer on a top surface of the pillars; applying a metal coating on the metal layer on a top surface of the pillars, the metal layer defining a contact pattern of the VCSEL pillar array; and applying solder on the metal coating to flip chip mount the VCSEL pillar array to a substrate package.

A vertical cavity surface emitting laser (VCSEL) may include an epitaxial structure that includes a first active layer, a second active layer, and a tunnel junction therebetween. The VCSEL may include a set of contacts that are electrically connected to the epitaxial structure. The set of contacts may include three or more contacts, and the set of contacts may be electrically separated from each other on the VCSEL. At least one contact, of the set of contacts, may be electrically connected to the epitaxial structure at a depth between the first active layer and the second active layer.

An optoelectronic semiconductor component has a first semiconductor layer of a p-conductivity type, a second semiconductor layer of an n-conductivity type and also an n-doped current distribution layer containing ZnSe and adjoining the second semiconductor layer.

A laser device comprises a carrier, an optoelectronic component provided on the carrier, said component being designed to emit laser radiation, and an optical element designed to form the laser radiation emitted by the optoelectronic component, wherein: the optical element has a first layer that is at least partially transparent to the laser radiation, with a first refractive index, and a second layer that is at least partially transparent to the laser radiation, with a second refractive index; the first layer being applied to the optoelectronic component and having a surface with an imprinted structure; and the second layer is applied to the first layer, on the surface (24) having the imprinted structure.

A laser array includes a plurality of laser diodes arranged and electrically connected to one another on a surface of a non-native substrate. Respective laser diodes of the plurality of laser diodes have different orientations relative to one another on the surface of the non-native substrate. The respective laser diodes are configured to provide coherent light emission in different directions, and the laser array is configured to emit an incoherent output beam comprising the coherent light emission from the respective laser diodes. The output beam may include incoherent light having a non-uniform intensity distribution over a field of view of the laser array. Related devices and fabrication methods are also discussed.

The present disclosure pertains to a light source for a time-of-flight device having a vertical-cavity surface-emitting laser. The vertical-cavity surface-emitting laser has a liquid crystal section for providing light generated by the vertical-cavity surface-emitting laser at two or more distant wave-lengths.

A device and a method to produce an augmented-laser (ATLAS) comprising a bi-stable resistive system (BRS) integrated in series with a semiconductor laser. The laser exhibits reduction/inhibition of the Spontaneous Emission (SE) below lasing threshold by leveraging the abrupt resistance switch of the BRS. The laser system comprises a semiconductor laser and a BRS operating as a reversible switch. The BRS operates in a high resistive state in which a semiconductor laser is below a lasing threshold and emitting in a reduced spontaneous emission regime, and a low resistive state in which a semiconductor laser is above or equal to a lasing threshold and emitting in a stimulated emission regime. The BRS operating as a reversible switch is electrically connected in series across two independent chips or on a single wafer. The BRS is formed using insulator-to-metal transition (IMT) materials or is formed using threshold-switching selectors (TSS).

A microcavity pixel design and structure allowing for tuning the optical cavity length of the microcavity of a microcavity pixel structure. This is achieved by including an intermediate electrode in the device which has an overhang region to form a connecting area to a bottom electrode, alleviating design restrictions in material type and dimensions throughout the optical microcavity tuning process. A method for the fabrication of a multi-colored microcavity pixel array facilitating the use of blanket deposition methods for select layers within a microcavity pixel structure.

A device and a method to produce an augmented-laser (ATLAS) comprising a bi-stable resistive system (BRS) integrated in series with a semiconductor laser. The laser exhibits reduction/inhibition of the Spontaneous Emission (SE) below lasing threshold by leveraging the abrupt resistance switch of the BRS. The laser system comprises a semiconductor laser and a BRS operating as a reversible switch. The BRS operates in a high resistive state in which a semiconductor laser is below a lasing threshold and emitting in a reduced spontaneous emission regime, and a low resistive state in which a semiconductor laser is above or equal to a lasing threshold and emitting in a stimulated emission regime. The BRS operating as a reversible switch is electrically connected in series across two independent chips or on a single wafer. The BRS is formed using insulator-to-metal transition (IMT) materials or is formed using threshold-switching selectors (TSS).