Abstract: Broad spectrum light emitting devices and methods and semiconductor chips for fabricating such devices include a light emitting element, such as a diode or laser, which emits light in a predefined range of frequencies. The light emitting element includes a shaped substrate suitable for light extraction through the substrate and a cavity in the substrate proximate the light emitting element. For example, a trench adjacent the light emitting element may be provided. The cavity/trench is configured to contain light conversion material such that light extracted from sidewalls of the cavity/trench passes through the light conversion material contained in the cavity/trench. Methods of fabricating such devices and/or chips are also provided.

Abstract: Semiconductor light emitting devices, such as light emitting diodes, include a substrate, an epitaxial region on the substrate that includes a light emitting region such as a light emitting diode region, and a multilayer conductive stack including a current spreading layer, on the epitaxial region. A barrier layer is provided on the current spreading layer and extending on a sidewall of the current spreading layer. The multilayer conductive stack can also include an ohmic layer between the reflector and the epitaxial region. The barrier layer further extends on a sidewall of the ohmic layer. The barrier layer can also extend onto the epitaxial region outside the multilayer conductive stack. The barrier layer can be fabricated as a series of alternating first and second sublayers.

Abstract: An LED includes a chip having a light emitting surface, and a coating of phosphor-containing material on the light emitting surface. The phosphor-containing material comprises at least two quantities of different phosphor particles and are arranged in a densely packed layer within the coating at the light emitting surface. The densely packed layer of phosphor particles does not extend all the way through the coating.

Abstract: A submount for mounting an LED chip includes a substrate, a die attach pad configured to receive an LED chip on an upper surface of the substrate, a first meniscus control feature on the substrate surrounding the die attach pad and defining a first encapsulant region of the upper surface of the substrate, and a second meniscus control feature on the substrate surrounding the first encapsulant region and defining a second encapsulant region of the upper surface of the substrate. The first and second meniscus control features may be substantially coplanar with the die attach pad. A packaged LED includes a submount as described above and further includes an LED chip on the die attach pad, a first encapsulant on the substrate within the first encapsulant region, and a second encapsulant on the substrate within the second encapsulant region and covering the first encapsulant. Method embodiments are also disclosed.

Abstract: Light emitting devices include a Light Emitting Diode (LED) chip having an anode contact and a cathode contact on a face thereof. A solder mask extends from the gap between the contacts onto one or both of the contacts. The LED chip may be mounted on a printed circuit board without an intervening submount. Related fabrication methods are also described.

Abstract: An LED includes a chip having a light emitting surface, and a coating of phosphor-containing material on the light emitting surface. The phosphor-containing material comprises at least two quantities of different phosphor particles and are arranged in a densely packed layer within the coating at the light emitting surface. The densely packed layer of phosphor particles does not extend all the way through the coating.

Abstract: High voltage array light emitting devices, fixtures and methods are disclosed. In one embodiment a light emitting device can include a submount, a light emission area disposed over the submount and a retention material adapted to be dispensed about the light emission area. The light emitting device can be operable at high voltages which are greater than approximately 40 volts (V). In one aspect, the retention material can be least partially disposed within the light emission area such that the retention material physically separates a first section of the light emission area from a second section of the light emission area.

Abstract: An LED includes a chip having a light emitting surface, and a coating of phosphor-containing material on the light emitting surface. Phosphor particles are arranged in a densely packed layer within the coating at the light emitting surface, and such that the light emitting surface is in contacting relationship with the phosphor particles.

Abstract: Semiconductor light emitting devices, such as light emitting diodes, include a substrate, an epitaxial region on the substrate that includes a light emitting region such as a light emitting diode region, and a multilayer conductive stack including a current spreading layer, on the epitaxial region. A barrier layer is provided on the current spreading layer and extending on a sidewall of the current spreading layer. The multilayer conductive stack can also include an ohmic layer between the reflector and the epitaxial region. The barrier layer further extends on a sidewall of the ohmic layer. The barrier layer can also extend onto the epitaxial region outside the multilayer conductive stack. The barrier layer can be fabricated as a series of alternating first and second sublayers.

Abstract: Semiconductor light emitting devices, such as light emitting diodes, include a substrate, an epitaxial region on the substrate that includes a light emitting region such as a light emitting diode region, and a multilayer conductive stack including a reflector layer, on the epitaxial region. A barrier layer is provided on the reflector layer and extending on a sidewall of the reflector layer. The multilayer conductive stack can also include an ohmic layer between the reflector and the epitaxial region. The barrier layer further extends on a sidewall of the ohmic layer. The barrier layer can also extend onto the epitaxial region outside the multilayer conductive stack. The barrier layer can be fabricated as a series of alternating first and second sublayers.

Abstract: A method of forming a lens over an optoelectronic element includes providing the optoelectronic element on a support substrate, dispensing a quantity of encapsulant onto the support substrate over the optoelectronic element, inverting the support substrate so that the support substrate is above the optoelectronic element and the encapsulant is suspended from the support substrate, and curing the encapsulant while maintaining the support substrate in the inverted position.

Abstract: Light emitter packages having multiple light emitter chips, such as light emitting diode (LED) chips, and related methods are provided. In one embodiment, a light emitter package can include a ceramic submount. An array of light emitter chips can be disposed over a portion of the submount, and each light emitter chip can include a horizontal chip structure having positive and negative electrical contacts disposed on a same side. The positive and negative electrical contacts can be adapted to electrically communicate to conductive portions of the submount. Light emitter packages can further include a lens overmolded on the submount and covering a portion of the array.

Abstract: A method of forming can be provided by applying an optical conversion material to a mold to form a unitary layer of optical conversion material and removing the unitary layer of optical conversion material from the mold.

Abstract: A light-emitting device comprising (a) a submount having front and back sides and including a ceramic layer; (b) an array of light-emitting diodes (LEDs) on the front side; and (c) a lens overmolded on the submount and covering the LED array. In some embodiments, the submount comprises at least two electrically-conductive contact pads on the front side, and each LED in the array is secured with respect to one of the contact pads.

Abstract: Provided are apparatus and methods corresponding to a solid state light emitting element. Such methods include mounting, to a thermally conductive component, a solid state light emitting element that includes first and second electrical connection points that are configured to be conductively engaged on a first side of a circuit structure. The solid state light emitting element is electrically insulated from the thermally conductive component to provide that electrical connections are arranged on the first side of the circuit structure and heat is conducted to a second side of the circuit structure that is opposite the first side of the circuit structure.

Abstract: An LED includes a chip having a light emitting surface, and a coating of phosphor-containing material on the light emitting surface. Phosphor particles are arranged in a densely packed layer within the coating at the light emitting surface, and such that the light emitting surface is in contacting relationship with the phosphor particles.

Abstract: A submount for an electronic device includes an electrically insulating substrate including first and second surfaces and having a thickness between the first and second surfaces, a thermally conductive pad on the first surface of the substrate, and a thermally conductive via extending from the first surface of the substrate toward the second surface of the substrate and having a length that is less than the thickness of the substrate. The thermally conductive via has a higher thermal conductivity than a thermal conductivity of the substrate. Methods of forming submounts are also disclosed.

Abstract: Methods of forming a light emitting device package assembly include defining a chromaticity region in a two dimensional chromaticity space within a 10-step MacAdam ellipse of a target chromaticity point, and subdividing the defined chromaticity region into at least three chromaticity subregions, providing a plurality of light emitting devices that emit light having a chromaticity that falls within the defined chromaticity region, selecting at least three of the plurality of light emitting devices, wherein each of the three light emitting devices emits light from a different one of the chromaticity subregions. The at least three light emitting devices are selected from chromaticity subregions that are complementary relative to the target chromaticity point to at least one other chromaticity subregion from which a light emitting device is selected.