A VCSEL device includes a substrate and a first DBR structure disposed on the substrate. The VCSEL device further includes a cathode contact disposed on a top surface of the first DBR structure. In addition, the VCSEL device includes a VCSEL mesa that is disposed on the top surface of the first DBR structure. The VCSEL mesa includes a quantum well, a non-circularly-shaped oxide aperture region disposed above the quantum well, and a second DBR structure disposed above the non-circularly-shaped oxide aperture region. In addition, the VCSEL mesa includes a selective polarization structure disposed above the second DBR structure and an anode contact disposed above the selective polarization structure.

This disclosure provides methods and apparatuses for sorting target particles. In various embodiments, the disclosure provides a cassette for sorting target particles, methods for sorting target particles, methods of loading a microchannel for maintaining sample material viability, methods of quantifying sample material, and an optical apparatus for laser scanning and particle sorting.

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 laser diode and a method for manufacturing a laser diode are disclosed. In an embodiment a laser diode includes a surface emitting semiconductor laser configured to emit electromagnetic radiation and an optical element arranged downstream of the semiconductor laser in a radiation direction, wherein the optical element includes a diffractive structure or a meta-optical structure or a lens structure, and wherein the optical element and the semiconductor laser are cohesively connected to each other.

A laser arrangement includes a VCSEL array comprising multiple VCSELs arranged on a common semiconductor substrate, an optical structure, and a diffusor structure. The optical structure is arranged to reduce a divergence angle of laser light emitted by each respective VCSEL to a section of the diffusor structure assigned to the respective VCSEL. The diffusor structure is arranged to transform the laser light received from the optical structure to transformed laser light such that a continuous illumination pattern is configured to be provided in a reference plane in a defined field-of-view. The diffusor structure is arranged to increase a size of the illumination pattern in comparison to an untransformed illumination pattern which can be provided without the diffusor structure. The VCSEL array, optical structure, and diffusor structure are arranged such that sections of the diffusor structure do not overlap. Diffusor properties of the diffusor structure vary across the diffusor structure.

A VCSEL array has VCSELs on a semiconductor substrate and has a prismatic or Fresnel optical structure, which is arranged to transform laser light to provide a continuous illumination pattern in a reference plane. The optical structure increases a size of the illumination pattern in comparison to an untransformed illumination pattern. The optical structure is arranged such that each VCSEL illuminates a sector of the pattern. Sub-surfaces of the optical structure with different height above the semiconductor substrate are arranged next to each other. Each VCSEL is associated with a sub-surface. A distance between each VCSEL and a size of its sub-surface is arranged such that the VCSEL illuminates only a part of the sub-surface without illuminating one of the steps. The VCSEL array has an array of microlenses, each VCSEL being associated with a microlens arranged to collimate the laser light after traversing the optical structure.

A light emitting element includes: a laminated structure 20 obtained by laminating a first compound semiconductor layer 21, an active layer 23, and a second compound semiconductor layer 22; a first light reflecting layer 41 disposed on a first surface side of the first compound semiconductor layer 21; a second light reflecting layer 42 disposed on a second surface side of the second compound semiconductor layer 22; and light convergence/divergence changing means 50. The first light reflecting layer 41 is formed on a concave mirror portion 43. The second light reflecting layer 42 has a flat shape. When light generated in the active layer 23 is emitted to the outside, a light convergence/divergence state before the light is incident on the light convergence/divergence changing means 50 is different from a light convergence/divergence state after the light passes through the light convergence/divergence changing means 50.

A VCSELNECSEL array design is disclosed that results in arrays that can be directly soldered to a PCB using conventional surface-mount assembly and soldering techniques for mass production. The completed VCSEL array does not need a separate package and no precision sub-mount and flip-chip bonding processes are required. The design allows for on-wafer probing of the completed arrays prior to singulation of the die from the wafer. Embodiments relate to semiconductor devices, and more particularly to multibeam arrays of semiconductor lasers for high power and high frequency applications and methods of making and using the same.

A vertical-cavity surface-emitting laser (VCSEL) may include a substrate and a set of epitaxial layers on the substrate. The set of epitaxial layers may include a first mirror and a second mirror, an active region between the first mirror and the second mirror, and an oxidation layer to provide optical and electrical confinement in the VCSEL. The oxidation layer may be near the first mirror. The set of epitaxial layers may include an oxide lens to control a characteristic of an output beam emitted by the VCSEL. The oxide lens may be separate from the oxidation layer, and may be a lens that is separate from the first mirror and from the second mirror.

A vertical-cavity surface-emitting laser for near-field illumination of an eye includes a semiconductor substrate, a first reflector, a mesa region, a first electrical contact, and a second electrical contact. The first reflector is disposed on a first side of the semiconductor substrate and the mesa region is disposed on the first reflector. The mesa region includes a second reflector and an active region, where the mesa region is configured to generate a diverging infrared beam. The first electrical contact is disposed on a second side of the semiconductor substrate, opposite the first side, for electrically coupling to the first reflector. The second electrical contact is also disposed on the second side of the semiconductor substrate for electrically coupling to the second reflector.