A vertical cavity surface emitting laser includes a substrate that has a main surface including a first area and a second area, a post that is provided on or above the first area, and that includes a first-conductive first distributed Bragg reflector provided on or above the first area, an active layer provided on the first distributed Bragg reflector, and a second-conductive second distributed Bragg reflector provided on the active layer, a stack that is provided on or above the main surface, and that includes an upper surface having at least one recess portion disposed above the second area, a resin portion that is disposed in the at least one recess portion, and an electrode pad that is provided on the resin portion and that is electrically connected to either one of the first distributed Bragg reflector and the second distributed Bragg reflector.

A laser diode includes a semiconductor structure of a lower Bragg reflector layer, an active region, and an upper Bragg reflector layer. The upper Bragg reflector layer includes a lasing aperture having an optical axis oriented perpendicular to a surface of the active region. The active region includes a first material, and the lower Bragg reflector layer includes a second material, where respective lattice structures of the first and second materials are independent of one another. Related laser arrays and methods of fabrication are also discussed.

A Vertical Cavity Surface Emitting Laser (VCSEL) includes a layer stack of semiconductor layers having a first layer sub-stack forming a mesa, and a second layer sub-stack adjacent to the mesa in a stacking direction. Layers of the second layer sub-stack extend beyond layers of the first sub-stack in a direction perpendicular to the stacking direction. The semiconductor layers of the layer stack form an optical resonator having a first mirror, a second mirror, an active region between the first and second mirrors for laser light generation, and an oxide aperture layer forming a current aperture. The oxide aperture layer is made from Al.sub.1-xGa.sub.xAs with 0≤x≤0.05. The oxide aperture layer is a last layer of the mesa and immediately adjacent to a first layer of the second layer sub-stack. A first layer of the second layer sub-stack is a contact layer.

Provided is a back side emitting light source array device and an electronic apparatus, the back side emitting light source array device includes a substrate, a distributed Bragg reflector (DBR) provided on a first surface of the substrate, a plurality of gain layers which are provided on the DBR, the plurality of gain layers being spaced apart from one another, and each of the plurality of gain layers being configured to individually generate light, and a nanostructure reflector provided on the plurality of gain layers opposite to the DBR, and including a plurality of nanostructures having a sub-wavelength shape dimension, wherein a reflectivity of the DBR is less than a reflectivity of the nanostructure reflector such that the light generated is emitted through the substrate.

A vertical cavity surface emitting device includes a substrate, a first multilayer film reflecting mirror on the substrate, a first semiconductor layer on the first multilayer film reflecting mirror, a light-emitting layer on the first semiconductor layer, and a second semiconductor layer on the light-emitting layer. The second semiconductor layer includes a low resistance region and a high resistance region on an upper surface. The high resistance region is depressed from the low resistance region toward the light-emitting layer outside the low resistance region and impurities of the second conductivity type are inactivated in the high resistance region such that the high resistance region has an electrical resistance higher than an electrical resistance of the low resistance region. A light-transmitting electrode layer is in contact with the low resistance region and the high resistance region, and a second multilayer film reflecting mirror is on the light-transmitting electrode layer.

A semiconductor device comprising: a layered structure 20 configured by layering a first compound semiconductor layer 21, an active layer 23, and a second compound semiconductor layer 22; a substrate 11; a first light reflecting layer 41 arranged on the first surface side of the first compound semiconductor layer 21; and a second light reflecting layer 42 arranged on the second surface side of the second compound semiconductor layer 22, wherein the second light reflecting layer 42 has a flat shape; a concave surface portion 12 is formed on a substrate surface 11b; the first light reflecting layer 41 is formed on at least the concave surface portion 12; the first compound semiconductor layer 21 is formed to extend from the substrate surface 11b onto the concave surface portion 12; and a cavity is present between the first light reflecting layer 41 formed on the concave surface portion 12 and the first compound semiconductor layer 21.

A method of fabricating vertical cavity surface emitting laser, comprising: providing a first substrate formed with a dielectric DBR and a first bonding layer, and a second substrate formed with a etch-stop layer, a heavily doped layer, an active region, a current-confinement layer, and an arsenide DBR firstly, then sticking a third substrate on the arsenide DBR, then removing the second substrate and the etch-stop layer, next bonding the heavily doped layer to the dielectric DBR, next removing the third substrate, finally forming a p-type electrode contact and an n-type electrode contact.

A method for removing devices from a substrate using a supporting plate. One or more bars comprised of semiconductor layers are formed on a substrate, and one or more device structures are formed on the bars. At least one supporting plate is bonded to the bars, and stress is applied to the supporting plate to remove the bars from the substrate. The supporting plate is used to divide the bars into one or more device units after the bars are removed from the substrate, wherein the device units are packaged and arranged into one or more modules. The supporting plate may also be used to make a cleavage facet for one or more of the device structures after the bars are removed from the substrate.

A light emitting element includes: a laminated structural body 20 in which a first compound semiconductor layer 21, an active layer 23, and a second compound semiconductor layer 22 are laminated; a first electrode 31 electrically connected to the first compound semiconductor layer 21; and a second electrode 32 and a second light reflecting layer 42 formed on the second compound semiconductor layer 22, in which a protrusion 43 is formed on the first surface side of the first compound semiconductor layer 21, a smoothing layer 44 is formed on at least the protrusion 43, the protrusion 43 and the smoothing layer 44 constitute a concave mirror portion, a first light reflecting layer 41 is formed on at least a part of the smoothing layer 44, and the second light reflecting layer 42 has a flat shape.

The technology relates to producing an optoelectronic device. A method for forming an optoelectronic device on a substrate may include growing an epitaxial structure on the substrate, wherein the substrate comprises a semiconductor material having a lattice constant between 5.7 and 6.0 Angstroms, and wherein the epitaxial structure includes an epitaxial device layer, then depositing a metal layer on the epitaxial structure, and selectively removing the epitaxial layer, thereby separating the optoelectronic device from the substrate. An optoelectronic device may include an optoelectronic device structure including an epitaxial device layer having a lattice constant between 5.7 and 6.0 Angstroms, a metal layer deposited onto a surface of the optoelectronic device structure, and a carrier structure, wherein the optoelectronic device comprises a thin film, single crystal device.