| Patent application number | Description | Published |
|---|
| 20080224164 | Light Emitting Device with a Nanocrystalline Silicon Embedded Insulator Film - A light emitting device using a silicon (Si) nanocrystalline Si insulating film is presented with an associated fabrication method. The method provides a doped semiconductor or metal bottom electrode. Using a high density plasma-enhanced chemical vapor deposition (HDPECVD) process, a Si insulator film is deposited overlying the semiconductor electrode, having a thickness in a range of 30 to 200 nanometers (nm). For example, the film may be SiOx, where X is less than 2, Si3Nx, where X is less than 4, or SiCx, where X is less than 1. The Si insulating film is annealed, and as a result, Si nanocrystals are formed in the film. Then, a transparent metal electrode is formed overlying the Si insulator film. An annealed Si nanocrystalline SiOx film has a turn-on voltage of less than 20 volts, as defined with respect to a surface emission power of greater than 0.03 watt per square meter. | 09-18-2008 |
| 20080224205 | Vertical Thin-Film Transistor with Enhanced Gate Oxide - A method is provided for forming a low-temperature vertical gate insulator in a vertical thin-film transistor (V-TFT) fabrication process. The method comprises: forming a gate, having vertical sidewalls and a top surface, overlying a substrate insulation layer; depositing a silicon oxide thin-film gate insulator overlying the gate; plasma oxidizing the gate insulator at a temperature of less than 400° C., using a high-density plasma source; forming a first source/drain region overlying the gate top surface; forming a second source/drain region overlying the substrate insulation layer, adjacent a first gate sidewall; and, forming a channel region overlying the first gate sidewall, in the gate insulator interposed between the first and second source/drain regions. When the silicon oxide thin-film gate insulator is deposited overlying the gate a Si oxide layer, a low temperature deposition process can be used, so that a step-coverage of greater than 65% can be obtained. | 09-18-2008 |
| 20080266689 | Non-stoichiometric SiOxNy optical filters - A non-stoichiometric SiO | 10-30-2008 |
| 20080305566 | Silicon Nanocrystal Embedded Silicon Oxide Electroluminescence Device with a Mid-Bandgap Transition Layer - A method is provided for forming a silicon (Si) nanocrystal embedded Si oxide electroluminescence (EL) device with a mid-bandgap transition layer. The method provides a highly doped Si bottom electrode, and forms a mid-bandgap electrically insulating dielectric film overlying the electrode. A Si nanocrystal embedded SiOx film layer is formed overlying the mid-bandgap electrically insulating dielectric film, where X is less than 2, and a transparent top electrode overlies the Si nanocrystal embedded SiOx film layer. The bandgap of the mid-bandgap dielectric film is about half that of the bandgap of the Si nanocrystal embedded SiOx film. In one aspect, the Si nanocrystal embedded SiOx film has a bandgap (Eg) of about 10 electronvolts (eV) and mid-bandgap electrically insulating dielectric film has a bandgap of about 5 eV. By dividing the high-energy tunneling processes into two lower energy tunneling steps, potential damage due to high power hot electrons is reduced. | 12-11-2008 |
| 20090033206 | Graded Junction Silicon Nanocrystal Embedded Silicon Oxide Electroluminescence Device - A silicon (Si) nanocrystal embedded Si oxide electroluminescence (EL) device and associated fabrication process are presented. The method provides a substrate bottom electrode, and forms a plurality of Si nanocrystal embedded SiOx film layers overlying the bottom electrode, where X is less than 2. Each SiOx film layer has a Si excess concentration in a range of about 5 to 30%. The outside film layers sandwich an inner film layer having a lower concentration of Si nanocrystals. Alternately stated, the outside Si nanocrystal embedded SiOx film layers have a higher electrical conductivity than a sandwiched inner film layer. A transparent top electrode is formed over the plurality of Si nanocrystal embedded SiOx film layers. The plurality of Si nanocrystal embedded SiOx film layers are deposited using a high density plasma-enhanced chemical vapor deposition (HD PECVD) process. The HD PECVD process initially deposits SiOx film layers, which are subsequently annealed. | 02-05-2009 |
| 20090033207 | High Quantum Efficiency Silicon Nanoparticle Embedded SiOxNy Luminescence Device - A method is provided for fabricating a high quantum efficiency silicon (Si) nanoparticle embedded SiO | 02-05-2009 |
| 20090040599 | Optical Waveguide Amplifier Using High Quantum Efficiency Silicon Nanocrystal Embedded Silicon Oxide - A method is provided for optical amplification using a silicon (Si) nanocrystal embedded silicon oxide (SiOx) waveguide. The method provides a Si nanocrystal embedded SiOx waveguide, where x is less than 2, having a quantum efficiency of greater than 10%. An optical input signal is supplied to the Si nanocrystal embedded SiOx waveguide, having a first power at a first wavelength in the range of 700 to 950 nm. The Si nanocrystal embedded SiOx waveguide is pumped with an optical source having a second power at a second wavelength in a range of 250 to 550 nm. As a result, an optical output signal having a third power is generated, greater than the first power, at the first wavelength. In one aspect, the third power increases in response to the length of the waveguide strip. | 02-12-2009 |
| 20090058266 | Fabrication of a Semiconductor Nanoparticle Embedded Insulating Film Luminescence Device - A method is provided for fabricating a semiconductor nanoparticle embedded Si insulating film for short wavelength luminescence applications. The method provides a bottom electrode, and deposits a semiconductor nanoparticle embedded Si insulating film, including the element of N, O, or C, overlying the bottom electrode. After annealing, a semiconductor nanoparticle embedded Si insulating film has a peak photoluminescence (PL) at a wavelength in the range of 475 to 750 nanometers. | 03-05-2009 |
| 20090115311 | Fabrication of a Semiconductor Nanoparticle Embedded Insulating Film Electroluminescence Device - A method is provided for fabricating a semiconductor nanoparticle embedded Si insulating film for electroluminescence (EL) applications. The method provides a bottom electrode, and deposits a semiconductor nanoparticle embedded Si insulating film, including an element selected from a group consisting of N and C, overlying the bottom electrode. After annealing, a semiconductor nanoparticle embedded Si insulating film is formed having an extinction coefficient (k) in a range of 0.01-1.0, as measured at about 632 nanometers (nm), and a current density (J) of greater than 1 Ampere per square centimeter (A/cm | 05-07-2009 |
| 20090217968 | Silicon Oxide-Nitride-Carbide with Embedded Nanocrystalline Semiconductor Particles - A solar call is provided along with a method for forming a semiconductor nanocrystalline silicon insulating thin-film with a tunable bandgap. The method provides a substrate and introduces a silicon (Si) source gas with at least one of the following source gases: germanium (Ge), oxygen, nitrogen, or carbon into a high density (HD) plasma-enhanced chemical vapor deposition (PECVD) process. A SiOxNyCz thin-film embedded with a nanocrystalline semiconductor material is deposited overlying the substrate, where x, y, z≧0, and the semiconductor material is Si, Ge, or a combination of Si and Ge. As a result, a bandgap is formed in the SiOxNyCz thin-film, in the range of about 1.9 to 3.0 electron volts (eV). Typically, the semiconductor nanoparticles have a size in a range of 1 to 20 nm. | 09-03-2009 |
| 20090232449 | Erbium-Doped Silicon Nanocrystalline Embedded Silicon Oxide Waveguide - An erbium (Er)-doped silicon (Si) nanocrystalline embedded silicon oxide (SiOx) waveguide and associated fabrication method are presented. The method provides a bottom layer, and forms an Er-doped Si nanocrystalline embedded SiOx film waveguide overlying the bottom layer, having a minimum optical attenuation at about 1540 nanometers (nm). Then, a top layer is formed overlying the Er-doped SiOx film. The Er-doped SiOx film is formed by depositing a silicon rich silicon oxide (SRSO) film using a high density plasma chemical vapor deposition (HDPCVD) process and annealing the SRSO film. After implanting Er | 09-17-2009 |
| 20090294885 | Silicon Nanoparticle Embedded Insulating Film Photodetector - A photodetector is provided with a method for fabricating a semiconductor nanoparticle embedded Si insulating film for photo-detection applications. The method provides a bottom electrode and introduces a semiconductor precursor and hydrogen. A thin-film is deposited overlying the substrate, using a high density (HD) plasma-enhanced chemical vapor deposition (PECVD) process. As a result, a semiconductor nanoparticle embedded Si insulating film is formed, where the Si insulating film includes either N or C elements. For example, the Si insulating film may be a non-stoichiometric SiO | 12-03-2009 |
| 20100278475 | Light Emitting Device and Planar Waveguide with Single-Sided Periodically Stacked Interface - Light emitting and waveguide devices with single-sided photonic bandgaps are provided. The light emitting device is formed from a heavily doped silicon (Si) bottom electrode, and a Si-containing dielectric layer embedded Si nanoparticles overlying the bottom electrode. A transparent indium tin oxide (ITO) top electrode overlies the Si-containing dielectric layer, and a photonic bandgap (PBG) Bragg reflector underlies the Si bottom electrode. The PBG Bragg reflector includes at least one periodic bi-layer of films with different refractive indexes. The single-sided photonic bandgap planar waveguide interface is formed from a planar waveguide and a PBG Bragg reflector underlying the planar waveguide. | 11-04-2010 |
