Abstract: Thin flat crack-free freestanding nitride layers are fabricated by laser patterning of the interface and/or opposing surface of the nitride layer. The nitride layer is substantially flat once removed from the non-native substrate. The thin flat crack free nitride layers are between 3 and 250 microns thick and can have areas greater than 1 cm2.

Abstract: A substrate-free semiconducting sheet has an array of semiconducting elements dispersed in a matrix material. The matrix material is bonded to the edge surfaces of the semiconducting elements and the substrate-free semiconducting sheet is substantially the same thickness as the semiconducting elements.

Abstract: Solid state light sources based on LEDs mounted on or within thermally conductive luminescent elements provide both convective and radiative cooling. Low cost self-cooling solid state light sources can integrate the electrical interconnect of the LEDs and other semiconductor devices. The thermally conductive luminescent element can completely or partially eliminate the need for any additional heatsinking means by efficiently transferring and spreading out the heat generated in LED and luminescent element itself over an area sufficiently large enough such that convective and radiative means can be used to cool the device.

Abstract: Reflector designs for a large area panel light source create induced draft cooling means adjacent to the panel light source. The panel light source has a wavelength conversion element on a solid state light source for emitting light of a first and second wavelength to form a broader emission spectrum of light from the panel light source.

Abstract: A wavelength conversion chip is formed by depositing a wavelength conversion material on a substrate to form a layer, removing the resulting wavelength conversion layer from the substrate and then segmenting the wavelength conversion layer into a plurality of wavelength conversion chips. The wavelength conversion material can be annealed by thermal annealing or radiation annealing to increase the wavelength conversion efficiency of the chips or to sinter the wavelength conversion material to form a ceramic material. Optical coatings, vias, light extraction elements, electrical connections or electrical bond pads can be fabricated on the wavelength conversion chips.

Abstract: Solid state light sources based on LEDs mounted on or within thermally conductive luminescent elements provide both convective and radiative cooling. Low cost self-cooling solid state light sources can integrate the electrical interconnect of the LEDs and other semiconductor devices. The thermally conductive luminescent element can completely or partially eliminate the need for any additional heatsinking means by efficiently transferring and spreading out the heat generated in LED and luminescent element itself over an area sufficiently large enough such that convective and radiative means can be used to cool the device.

Abstract: High temperature semiconducting materials in a freestanding epitaxial chip enables the use of high temperature interconnect and bonding materials. Process materials can be used which cure, fire, braze, or melt at temperatures greater than 400 degrees C. These include, but are not limited to, brazing alloys, laser welding, high-temperature ceramics and glasses. High temperature interconnect and bonding materials can additionally exhibit an index of refraction intermediate to that of the freestanding epitaxial chip and its surrounding matrix. High index, low melting point glasses provide a hermetic seal of the semiconductor device and also index match the freestanding epitaxial chip thereby increasing extraction efficiency. In this manner, a variety of organic free semiconducting devices, such as solid-sate lighting sources, can be created which exhibit superior life, efficiency, and environmental stability.

Abstract: A solid-state light source includes at least one stack of light emitting elements. The elements are an inorganic light emitting diode chip and at least one wavelength conversion chip or the elements are a plurality of light emitting diode chips and one or more optional wavelength conversion chips. The wavelength conversion chip may include an electrical interconnection means. The light emitting diode chip may include at least one GaN-based semiconductor layer that is at least ten microns thick and that is fabricated by hydride vapor phase epitaxy. A method is described for fabricating the solid-state light source.

Abstract: Additional power and cooling can be provided for microprojectors by supplemental rechargeable power sources that can be integrated into memory sticks or by expansion cards that can plug into cellphones, PDAs and other portable devices. A docking station for portable devices using microprojectors contains supplemental power, cooling means, addition data/audio/video interfaces, touch screen/optical interface, projection optics, contrast enhancing screens and/or addition optics for video conferencing. Optics can be adapted to the microprojector for better imaging, secured communications, enhanced light sources, low versus high power operation ratios, and contrast enhancing screens.

Abstract: High temperature bonding and interconnect methods can be used for LED and other optoelectronic devices based on freestanding nitride devices. Inorganic glasses, especially those which exhibit a CTE, which substantially matches the CTE of the freestanding nitride devices, can provide hermetic sealing of the freestanding nitride devices or the contact regions of the freestanding nitride devices. The freestanding nitride devices are typically freestanding nitride veneers.

Abstract: The reflectivity of mixed color LEDs, for example, red, green, and blue LEDs, and the resulting efficiency of a mixed color recycling light cavity can be increased by over-coating each LED with a multi-layer thin film coating comprising a dichroic filter. The thin film, dichroic filter coatings transmit the light emitted by the LED and reflect the light emanating from the other colors within the cavity. By utilizing high efficiency dichroic coatings, the reflectivity of the LEDs to the alternate wavelengths of the light emitted by other LEDs in the cavity can be raised to over 90%. By increasing the reflectivity of the LEDs for other colors, the optical radiation absorbed by the LEDs is decreased, thereby lowering the operation temperature and junction temperature of the LEDS. Lowering the operation temperature and junction temperature of the LEDS contributes to more efficient operation of the LEDs improving Lumen/Watt performance.

Abstract: Thin freestanding nitride veneers can be used for the fabrication of semiconductor devices. These veneers are typically less than 100 microns thick. The use of thin veneers also eliminates the need for subsequent wafer thinning for improved thermal performance and 3D packaging.

Abstract: Direct attach or surface mount LEDs are mounted onto a flat, thermally conductive, substrate, which is folded to form a light recycling cavity. A planar substrate is first coated with a metal layer, which is patterned to electrically connect the LEDs. The direct attach or surface mount LEDs are mounted on the substrate. The substrate is then scribed on the backside to form cut channels which form the folds. The direct attach or surface mount LEDs are then attached onto the metal layer on the substrate. The substrate is then folded into a light recycling cavity where the direct attach or surface mount LEDs are facing the inside of the cavity.

Abstract: A solid-state light source has a wavelength conversion chip affixed to a light emitting diode. Optical coatings, vias, light extraction elements, electrical connections or electrical bond pads can be fabricated on the wavelength conversion chips.

Abstract: Thin freestanding nitride films are used as a growth substrate to enhance the optical, electrical, mechanical and mobility of nitride based devices and to enable the use of thick transparent conductive oxides. Optoelectronic devices such as LEDs, laser diodes, solar cells, biomedical devices, thermoelectrics, and other optoelectronic devices may be fabricated on the freestanding nitride films. The refractive index of the freestanding nitride films can be controlled via alloy composition. Light guiding or light extraction optical elements may be formed based on freestanding nitride films with or without layers. Dual sided processing is enabled by use of these freestanding nitride films. This enables more efficient output for light emitting devices and more efficient energy conversion for solar cells.

Abstract: A self-cooling emitter is a light emitting element embedded within a thermally conductive luminescent element which functions as a thermal cooling means and wavelength conversion of the light emitting element. The thermally conductive luminescent element exhibits a bulk thermal conductivity greater than 1 W/m/K such that there is sufficient thermal spreading of the heat generated by the light emitting element.

Abstract: A substrate-free semiconducting sheet has an array of semiconducting elements dispersed in a matrix material. The matrix material is bonded to the edge surfaces of the semiconducting elements and the substrate-free semiconducting sheet is substantially the same thickness as the semiconducting elements.

Abstract: A substrate-free semiconducting sheet has an array of semiconducting elements dispersed in a matrix material. The matrix material is bonded to the edge surfaces of the semiconducting elements and the substrate-free semiconducting sheet is substantially the same thickness as the semiconducting elements.

Abstract: A wavelength conversion chip is formed by depositing a wavelength conversion material on a substrate to form a layer, removing the resulting wavelength conversion layer from the substrate and then segmenting the wavelength conversion layer into a plurality of wavelength conversion chips. The wavelength conversion material can be annealed by thermal annealing or radiation annealing to increase the wavelength conversion efficiency of the chips or to sinter the wavelength conversion material to form a ceramic material. Optical coatings, vias, light extraction elements, electrical connections or electrical bond pads can be fabricated on the wavelength conversion chips.

Abstract: LEDs are mounted onto a flat, thermally conductive, substrate, which is folded to form a light recycling cavity. A planar substrate is first coated with a metal layer, which is patterned to electrically connect the LEDs and to form bonding pads for wirebonds to connect the LEDs to external circuitry. The LEDs are mounted on the substrate. The substrate is then scribed on the backside to form the folds. The LED dies are then attached onto the metal islands (pads) defined on the substrate and wirebonds are used to connect the top side of the LED to adjacent patterned metal islands (pads) on the substrate. The substrate is then folded into a light recycling cavity where the LEDs are facing the inside of the cavity.