Abstract: A method is disclosed for treating a silicon carbide substrate for improved epitaxial deposition thereon and for use as a precursor in the manufacture of devices such as light emitting diodes. The method includes the steps of implanting dopant atoms of a first conductivity type into the first surface of a conductive silicon carbide wafer having the same conductivity type as the implanting ions at one or more predetermined dopant concentrations and implant energies to form a dopant profile, annealing the implanted wafer, and growing an epitaxial layer on the implanted first surface of the wafer.

Abstract: A physically robust light emitting diode is disclosed that offers high-reliability in standard packaging and that will withstand high temperature and high humidity conditions. The diode comprises a Group III nitride heterojunction diode with a p-type Group III nitride contact layer, an ohmic contact to the p-type contact layer, and a passivation layer on the ohmic contact. The diode is characterized in that it will emit at at least 50% of its original optical power and remain substantially unchanged in operating voltage after operating for at least 1000 hours at 10 miliamps in the environment of 85% relative humidity at a temperature of 85 C. An LED lamp incorporating the diode is also disclosed.

Abstract: A semiconductor device is disclosed that includes a semiconductor substrate having a first surface and a second surface and a first conductivity type and at least one epitaxial layer on the first surface of the semiconductor substrate. The epitaxial layer is formed of a material with a dissociation temperature below that of the semiconductor substrate. A zone of increased carrier concentration is in the semiconductor substrate and extends from the second surface of the semiconductor material toward the first surface. A layer of metal is deposited on the second surface of the semiconductor substrate and forms an ohmic contact at the interface of the metal and the zone of increased carrier concentration.

Abstract: A semiconductor structure is disclosed that enhances quality control inspection of device. The structure includes a substrate having at least one planar face, a first metal layer on the planar face, and covering some, but not all of the planar face in a first predetermined geometric pattern, and a second metal layer on the planar face, and covering some, but not all of the planar face in a second geometric pattern that is different from the first geometric pattern. A quality control method for manufacturing a semiconductor device is also disclosed. The method includes the steps of placing a first metal layer on a semiconductor face of a device in a first predetermined geometric pattern, placing a second metal layer on the same face of the device as the first layer and in a second predetermined geometric pattern that is different from the first geometric pattern, and then inspecting the device to identify the presence or absence of one or both of the patterns on the face.

Abstract: Light emitting device die having a mesa configuration on a substrate and an electrode on the mesa are attached to a submount in a flip-chip configuration by forming predefined pattern of conductive die attach material on at least one of the electrode and the submount and mounting the light emitting device die to the submount. The predefined pattern of conductive die attach material is selected so as to prevent the conductive die attach material from contacting regions of having opposite conductivity types when the light emitting device die is mounted to the submount. The predefined pattern of conductive die attach material may provide a volume of die attach material that is less than a volume defined by an area of the electrode and a distance between the electrode and the submount. Light emitting device dies having predefined patterns of conductive die attach material are also provided.

Abstract: The invention comprises a method for forming a metal-semiconductor ohmic contact (18) for use in a semiconductor device (10) having a plurality of epitaxial layers (14a-c) wherein the ohmic contact (18) is preferably formed after deposition of the epitaxial layers (14a-c). The invention also comprises a semiconductor device comprising a plurality of epitaxial layers and an ohmic contact.

Abstract: A light emitting diode includes a substrate having first and second opposing faces and a sidewall between the first and second opposing faces that extends at an oblique angle from the second face towards the first face. A conformal phosphor layer is provided on the oblique sidewall. The oblique sidewall can allow more uniform phosphor coatings than conventional orthogonal sidewalls.

Abstract: A vertical geometry light emitting diode is disclosed that is capable of emitting light in the red, green, blue, violet and ultraviolet portions of the electromagnetic spectrum. The light emitting diode includes a conductive silicon carbide substrate, an InGaN quantum well, a conductive buffer layer between the substrate and the quantum well, a respective undoped gallium nitride layer on each surface of the quantum well, and ohmic contacts in a vertical geometry orientation.

Abstract: Light emitting diodes include a substrate having first and second opposing faces and that is transparent to optical radiation in a predetermined wavelength range and that is patterned to define, in cross-section, a plurality of pedestals that extend into the substrate from the first face towards the second face. A diode region on the second face is configured to emit light in the predetermined wavelength range, into the substrate upon application of voltage across the diode region. A mounting support on the diode region, opposite the substrate is configured to support the diode region, such that the light that is emitted from the diode region into the substrate, is emitted from the first face upon application of voltage across the diode region. The first face of the substrate may include therein a plurality of grooves that define the plurality of triangular pedestals in the substrate. The grooves may include tapered sidewalls and/or a beveled floor.

Abstract: Bonding of flip-chip mounted light emitting devices having an irregular configuration is provided. Light emitting diodes having a shaped substrate are bonded to a submount by applying forces to the substrate an a manner such that shear forces within the substrate do not exceed a failure threshold of the substrate. Bonding a light emitting diode to a submount may be provided by applying force to a surface of a substrate of the light emitting diode that is oblique to a direction of motion of the light emitting diode to thermosonically bond the light emitting diode to the submount. Collets for use in bonding shaped substrates to a submount and systems for bonding shaped substrates to a submount are also provided.

Abstract: A method for forming an ohmic contact to silicon carbide for a semiconductor device comprises implanting impurity atoms into a surface of a silicon carbide substrate thereby forming a layer on the silicon carbide substrate having an increased concentration of impurity atoms, annealing the implanted silicon carbide substrate, and depositing a layer of metal on the implanted surface of the silicon carbide. The metal forms an ohmic contact “as deposited” on the silicon carbide substrate without the need for a post-deposition anneal step.

Abstract: Reflective ohmic contacts for n-type silicon carbide include a layer consisting essentially of nickel on the silicon carbide. The layer consisting essentially of nickel is configured to provide an ohmic contact to the silicon carbide, and to allow transmission therethrough of optical radiation that emerges from the silicon carbide. A reflector layer is on the layer consisting essentially of nickel, opposite the silicon carbide. A barrier layer is on the reflector layer opposite the layer consisting essentially of nickel, and a bonding layer is on the barrier layer opposite the reflector layer. It has been found that the layer consisting essentially of nickel and the reflector layer thereon can provide a reflective ohmic contact for silicon carbide that can have low ohmic losses and/or high reflectivity.

Abstract: Light emitting diodes include a substrate having first and second opposing faces and that is transparent to optical radiation in a predetermined wavelength range and that is patterned to define, in cross-section, a plurality of pedestals that extend into the substrate from the first face towards the second face. A diode region on the second face is configured to emit light in the predetermined wavelength range, into the substrate upon application of voltage across the diode region. A mounting support on the diode region, opposite the substrate is configured to support the diode region, such that the light that is emitted from the diode region into the substrate, is emitted from the first face upon application of voltage across the diode region. The first face of the substrate may include therein a plurality of grooves that define the plurality of triangular pedestals in the substrate. The grooves may include tapered sidewalls and/or a beveled floor.

Abstract: A semiconductor device is disclosed that includes a semiconductor substrate having a first surface and a second surface and a first conductivity type and at least one epitaxial layer on the first surface of the semiconductor substrate. The epitaxial layer is formed of a material with a dissociation temperature below that of the semiconductor substrate. A zone of increased carrier concentration is in the semiconductor substrate and extends from the second surface of the semiconductor material toward the first surface. A layer of metal is deposited on the second surface of the semiconductor substrate and forms an ohmic contact at the interface of the metal and the zone of increased carrier concentration.

Abstract: A component assembly system is provided that includes a longitudinally elongated tape carrier, a longitudinally elongated submount carrier, and an assembly machine. A plurality of components may be attached to the tape carrier. The assembly machine is adapted to receiving the tape carrier, with the components attached thereto, and to receive the submount carrier. The assembly machine is further adapted to bring the tape carrier in close proximity to the submount carrier, and to attach the components to the submounts on the submount carrier.

Abstract: Bonding of flip-chip mounted light emitting devices having an irregular configuration is provided. Light emitting diodes having a shaped substrate are bonded to a submount by applying forces to the substrate an a manner such that shear forces within the substrate do not exceed a failure threshold of the substrate. Bonding a light emitting diode to a submount may be provided by applying force to a surface of a substrate of the light emitting diode that is oblique to a direction of motion of the light emitting diode to thermosonically bond the light emitting diode to the submount. Collets for use in bonding shaped substrates to a submount and systems for bonding shaped substrates to a submount are also provided.

Abstract: Light emitting diodes include a substrate, an epitaxial region on the substrate that includes therein a diode region and a multilayer conductive stack on the epitaxial region opposite the substrate. A passivation layer extends at least partially on the multilayer conductive stack opposite the epitaxial region, to define a bonding region on the multilayer conductive stack opposite the epitaxial region. The passivation layer also extends across the multilayer conductive stack, across the epitaxial region and onto the substrate. The multilayer conductive stack can include an ohmic layer on the epitaxial region opposite the substrate, a reflector layer on the ohmic layer opposite the epitaxial region and a tin barrier layer on the reflector layer opposite the ohmic layer. An adhesion layer also may be provided on the tin barrier layer opposite the reflector layer. A bonding layer also may be provided on the adhesion layer opposite the tin barrier layer.

Abstract: A light emitting diode includes a substrate having first and second opposing faces and a sidewall between the first and second opposing faces that extends at an oblique angle from the second face towards the first face. A conformal phosphor layer is provided on the oblique sidewall. The oblique sidewall can allow more uniform phosphor coatings than conventional orthogonal sidewalls.

Abstract: A physically robust light emitting diode is disclosed that offers high-reliability in standard packaging and that will withstand high temperature and high humidity conditions. The diode comprises a Group III nitride heterojunction diode with a p-type Group III nitride contact layer, an ohmic contact to the p-type contact layer, and a passivation layer on the ohmic contact. The diode is characterized in that it will emit at least 50% of its original optical power and remain substantially unchanged in operating voltage after operating for at least 1000 hours at 10 milliamps in an environment of 85% relative humidity at a temperature of 85 C. An LED lamp incorporating the diode is also disclosed.

Abstract: Methods of forming a light emitting diode are provided by scoring a semiconductor substrate having a light emitting region formed thereon so as to provide score lines between individual ones of a plurality of light emitting diodes. The semiconductor substrate is then broken along selected ones of the score lines so as to provide a unitized subset of the plurality of light emitting diodes. The unitized subset includes at least two light emitting diodes. Electrical connections are provided to the light emitting diodes of the unitized subset of the plurality of light emitting diodes. The score lines may also define the individual ones of the light emitting diodes.