Apollo Diamond, Inc Patent applications |
Patent application number | Title | Published |
20120193644 | BORON-DOPED DIAMOND SEMICONDUCTOR - First and second synthetic diamond regions are doped with boron. The second synthetic diamond region is doped with boron to a greater degree than the first synthetic diamond region, and in physical contact with the first synthetic diamond region. In a further example embodiment, the first and second synthetic diamond regions form a diamond semiconductor, such as a Schottky diode when attached to at least one metallic lead. | 08-02-2012 |
20120164786 | GALLIUM NITRIDE LIGHT EMITTING DEVICES ON DIAMOND - Wide bandgap devices are formed on a diamond substrate, such as for light emitting diodes as a replacement for incandescent light bulbs and fluorescent light bulbs. In one embodiment, diodes (or other devices) are formed on diamond in at least two methods. A first method comprises growing a wide bandgap material on diamond and building devices on that grown layer. The second method involves bonding a wide bandgap layer (device or film) onto diamond and building the device onto the bonded layer. These devices may provide significantly higher efficiency than incandescent or fluorescent lights, and provide significantly higher light or energy density than other technologies. Similar methods and structures result in other wide bandgap semiconductor devices. | 06-28-2012 |
20120163406 | DIAMOND HEAT SINK IN A LASER - A laser has a laser material in thermal contact with a diamond, such that the diamond is operable to carry heat away from the laser material. In further embodiments, the diamond has a reduced nitrogen content, is a reduced carbon-13 content, is a monocrystalline or multilayer low-strain diamond, or has a thermal conductivity of greater than 2200 W/mK. | 06-28-2012 |
20120058602 | METHOD OF FORMING A WAVEGUIDE IN DIAMOND - N-V centers in diamond are created in a controlled manner. In one embodiment, a single crystal diamond is formed using a CVD process, and then annealed to remove N-V centers. A thin layer of single crystal diamond is then formed with a controlled number of N-V centers. The N-V centers form Qubits for use in electronic circuits. Masked and controlled ion implants, coupled with annealing are used in CVD formed diamond to create structures for both optical applications and nanoelectromechanical device formation. Waveguides may be formed optically coupled to the N-V centers and further coupled to sources and detectors of light to interact with the N-V centers. | 03-08-2012 |
20110054450 | DIAMOND MEDICAL DEVICES - Masked and controlled ion implants, coupled with annealing or etching are used in CVD formed single crystal diamond to create structures for both optical applications, nanoelectromechanical device formation, and medical device formation. Ion implantation is employed to deliver one or more atomic species into and beneath the diamond growth surface in order to form an implanted layer with a peak concentration of atoms at a predetermined depth beneath the diamond growth surface. The composition is heated in a non-oxidizing environment under suitable conditions to cause separation of the diamond proximate the implanted layer. Further ion implants may be used in released structures to straighten or curve them as desired. Boron doping may also be utilized to create conductive diamond structures. | 03-03-2011 |
20090311852 | BORON-DOPED DIAMOND SEMICONDUCTOR - First and second synthetic diamond regions are doped with boron. The second synthetic diamond region is doped with boron to a greater degree than the first synthetic diamond region, and in physical contact with the first synthetic diamond region. In a further example embodiment, the first and second synthetic diamond regions form a diamond semiconductor, such as a Schottky diode when attached to at least one metallic lead. | 12-17-2009 |