| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 257188000 | Having narrow energy band gap ( | 13 |
| 20100230720 | SEMICONDUCTOR DEVICE AND METHOD - The present invention is directed to a semiconductor device that includes at least one p-n junction including a p-type material, an n-type material, and a depletion region. The at least one p-n junction is configured to generate bulk photocurrent in response to incident light. The at least one p-n junction is characterized by a conduction band energy level, a valence band energy level and a surface Fermi energy level. The surface Fermi energy level is pinned either near or above the conduction band energy level or near or below the valence band energy level. A unipolar barrier structure is disposed in a predetermined region within the at least one p-n junction. The unipolar barrier is configured to raise the conduction band energy level if the surface Fermi energy level is pinned near or above the conduction band energy level or lower the valence band energy level if the surface Fermi energy level is pinned near or below the valence band energy level such that the unipolar barrier is configured to propagate the bulk photocurrent and substantially block surface leakage current. The at least one p-n junction and the unipolar barrier are integrally formed. | 09-16-2010 |
| 20110095334 | BARRIER PHOTODETECTOR WITH PLANAR TOP LAYER - A barrier-type photo-detector is provided with a Barrier between first and second layers. One of the layers is delineated into pixels without fully removing the non-pixel portions of the delineated layer. Delineation may be accomplished through material modification techniques such as ion damage, selective doping, ion induced disordering or layer material growth. Some variations may employ partial material removal techniques. | 04-28-2011 |
| 20110156097 | REDUCED DARK CURRENT PHOTODETECTOR - A photo-detector comprising: a photo absorbing layer comprising an n-doped semiconductor exhibiting a valence band energy level; a barrier layer, a first side of the barrier layer adjacent a first side of the photo absorbing layer, the barrier layer exhibiting a valence band energy level substantially equal to the valence band energy level of the doped semiconductor of the photo absorbing layer; and a contact area comprising a doped semiconductor, the contact area being adjacent a second side of the barrier layer opposing the first side, the barrier layer exhibiting a thickness and a conductance band gap sufficient to prevent tunneling of majority carriers from the photo absorbing layer to the contact area and block the flow of thermalized majority carriers from the photo absorbing layer to the contact area. Alternatively, a p-doped semiconductor is utilized, and conductance band energy levels of the barrier and photo absorbing layers are equalized. | 06-30-2011 |
| 20120273838 | MINORITY CARRIER BASED HgCdTe INFRARED DETECTORS AND ARRAYS - Disclosed are minority carrier based mercury-cadmium telluride (HgCdTe) infrared detectors and arrays, and methods of making, are disclosed. The constructions provided by the invention enable the detectors to be used at higher temperatures, and/or be implemented on less expensive semiconductor substrates to lower manufacturing costs. An exemplary embodiment a substrate, a bottom contact layer disposed on the substrate, a first mercury-cadmium telluride layer having a first bandgap energy value disposed on the bottom contact layer, a second mercury-cadmium telluride layer having a second bandgap energy value that is greater than the first bandgap energy value disposed on the first mercury-cadmium telluride layer, and a collector layer disposed on the second mercury-cadmium telluride layer, wherein the first and second mercury-cadmium telluride layers are each doped with an n-type dopant. | 11-01-2012 |
| 20120286328 | COMPOUND SEMICONDUCTOR LIGHT-RECEIVING ELEMENT ARRAY - An array structure solves issues that exist in conventional compound semiconductor photodiode arrays, such as large cross talk, large surface leaks, large stray capacitance, narrow detection wavelength bands, and bad manufacturing yield, simultaneously. A photodiode array has, laminated upon a semiconductor substrate, a buffer layer ( | 11-15-2012 |
| 20130062663 | DICHROMATIC PHOTODIODES - A dichromatic photodiode and method for dichromatic photodetection are disclosed. A wide bandgap junction comprises a lattice matched junction operable to detect a first light spectrum. A narrow bandgap junction is coupled to the wide bandgap junction, and comprises a photodiode structure. The narrow bandgap junction is operable to detect a second light spectrum. | 03-14-2013 |
| 20140319580 | P-N DIODE HAVING A CONTROLLED HETEROSTRUCTURE SELF-POSITIONED ON HGCDTE, FOR INFRARED IMAGERS - A device including at least one heterostructure p/n diode, including a substrate based on HgCdTe including for each diode: a first part having a first cadmium concentration; a concentrated part, having a second cadmium concentration, greater than the first concentration, forming a heterostructure with the first part; a p+ doped zone situated in the concentrated part and extending into the first part, forming a p/n junction with an n-doped position of the first part, or a base plate; and the concentrated part is only located in the p+ doped zone and forms a substantially constant cadmium concentration well. | 10-30-2014 |
| 257189000 | Layer is a group III-V semiconductor compound | 6 |
| 20090078963 | Nano-optoelectronic chip structure and method - The present invention relates to integrated structures of III-V and Silicon materials for making optoelectronic devices on chip compatible with complimentary metal oxide semiconductor (CMOS). As a result, various light generation, detection, switching, modulation, filtering, multiplexing, signal manipulation and beam splitting devices could be fabricated in semiconductor material such as silicon on insulator (SOI) and other material substrate. | 03-26-2009 |
| 20100289061 | Infrared photodetector - The infrared photodetector includes a contact layer formed over a semiconductor substrate | 11-18-2010 |
| 20110233609 | Method for Producing Infrared-Photosensitive Matrix Cells Adhering to an Optically Transparent Substrate by Molecular Adhesion, and Related Sensor - The invention relates to a method for producing an infrared radiation sensor, said sensor comprising an infrared photodiode array formed in a first material and a reading circuit formed in a second material, said method comprising the steps of: sticking, through molecular adhesion, a first material side surface onto an optically transparent crystalline material side surface having infrared radiation and a coefficient of thermal expansion similar to that of the second material, give or take 20%; thinning the body of the first material side surface so that the latter is less that 25 μm; producing infrared-sensitive photodiodes onto the thus-thinned first material side surface; depositing contact ball bearings onto the infrared photodiodes; and mounting the reading circuit onto the first material side surface through flip chip technology. | 09-29-2011 |
| 20110248316 | INFRARED DETECTOR WITH EXTENDED SPECTRAL RESPONSE IN THE VISIBLE FIELD - A semiconductor-based SWIR infrared detector sensitive to wavelengths shorter than about 2.5 microns comprises a stack of semiconductor layers based on III-V materials forming a PIN photodiode. The stack includes a naked electrical contact, called a lower electrical contact, serving as an optical window; and a detection layer sensitive to said wavelengths. The lower contact comprises at least one layer of indirect-bandgap III-V material(s) doped n-type, pseudomorphic or lattice matched with a substrate intended to serve as a temporary substrate possibly being made of a III-V material such as InP or GaAs or of silicon or germanium. | 10-13-2011 |
| 20120056243 | PHOTODETECTOR AND METHOD FOR MANUFACTURING PHOTODETECTOR - A photodetector | 03-08-2012 |
| 20140332848 | LOW-BANDGAP, MONOLITHIC, MULTI-BANDGAP, OPTOELECTRONIC DEVICES - Low bandgap, monolithic, multi-bandgap, optoelectronic devices ( | 11-13-2014 |
