Abstract: An array of pixels is formed using a substrate having a frontside and a backside that is for receiving incident light. Each pixel typically includes metallization layers included in the frontside of the substrate, a photosensitive region formed in the backside of the substrate, and a trench formed around the photosensitive region in the backside of the substrate. The trench causes the incident light to be directed away from the trench and towards the photosensitive region.

Abstract: A backside illuminated imaging sensor includes a semiconductor substrate, a metal interconnect layer and a light attenuating layer. The semiconductor substrate has a front surface, a back surface, and includes at least one imaging pixel formed on the front surface of the semiconductor substrate. The metal interconnect layer is electrically coupled to the imaging pixel and the light attenuating layer is coupled between the metal interconnect layer and the front surface of the semiconductor substrate. In operation, the imaging pixel receives light from the back surface of the semiconductor substrate, where a portion of the received light propagates through the imaging pixel to the light attenuating layer. The light attenuating layer is configured to substantially attenuate the portion of light received from the imaging pixel.

Abstract: A technique for fabricating an array of imaging pixels includes fabricating front side components on a front side of the array. After fabricating the front side components, a dopant layer is implanted on a backside of the array. A mask is formed over the dopant layer to selectively expose portions of the dopant layer. Next, the exposed portions of the dopant layer are laser annealed. Alternatively, the mask may be disposed over the backside prior to the formation of the dopant layer and the dopants implanted through the exposed portions and subsequently laser annealed.

Abstract: A backside illuminated imaging sensor includes a semiconductor having an imaging pixel that can include a photodiode region, an insulation layer, and a reflective layer. The photodiode is typically formed in the frontside of the semiconductor substrate. A surface shield layer can be formed on the frontside of the photodiode region. A light reflecting layer can be formed using silicided polysilicon on the frontside of the sensor. The photodiode region receives light from the back surface of the semiconductor substrate. When a portion of the received light propagates through the photodiode region to the light reflecting layer, the light reflecting layer reflects the portion of light received from the photodiode region towards the photodiode region. The silicided polysilicon light reflecting layer also forms a gate of a transistor for establishing a conductive channel between the photodiode region and a floating drain.

Abstract: An imaging sensor pixel array includes a semiconductor substrate, a plurality of active pixels and at least one black reference pixel. The plurality of active pixels are disposed in the semiconductor substrate for capturing an image. Each of the active pixels includes a first region for receiving light including a p-n junction for accumulating an image charge and active pixel circuitry coupled to the first region to readout the image charge. The black reference pixel is also disposed within the semiconductor substrate for generating a black level reference value. The black reference pixel includes a second region for receiving light without a p-n junction and black pixel circuitry coupled to the photodiode region without the p-n junction to readout a black level reference signal.

Abstract: A backside illuminated imaging sensor includes a semiconductor layer and an infrared detecting layer. The semiconductor layer has a front surface and a back surface. An imaging pixel includes a photodiode region formed within the semiconductor layer. The infrared detecting layer is disposed above the front surface of the semiconductor layer to receive infrared light that propagates through the imaging sensor from the back surface of the semiconductor layer.

Abstract: A backside illuminated imaging sensor includes a semiconductor layer, a metal interconnect layer and a silicide light reflecting layer. The semiconductor layer has a front surface and a back surface. An imaging pixel that includes a photodiode region is formed within the semiconductor layer. The metal interconnect layer is electrically coupled to the photodiode region and the silicide light reflecting layer is coupled between the metal interconnect layer and the front surface of the semiconductor layer. In operation, the photodiode region receives light from the back surface of the semiconductor layer, where a portion of the received light propagates through the photodiode region to the silicide light reflecting layer. The silicide light reflecting layer is configured to reflect the portion of light received from the photodiode region.

Abstract: An image sensor includes at least one photosensitive element disposed in a semiconductor substrate. Metal conductors may be disposed on the semiconductor substrate. A filter may be disposed between at least two individual metal conductors and a micro-lens may be disposed on the filter. There may be insulator material disposed between the metal conductors and the semiconductor substrate and/or between individual metal conductors. The insulator material may be removed so that the filter may be disposed on the semiconductor substrate.

Abstract: A backside illuminated imaging sensor includes a semiconductor substrate having a front surface and a back surface. The semiconductor substrate has at least one imaging array formed on the front surface. The imaging sensor also includes a carrier substrate to provide structural support to the semiconductor substrate, where the carrier substrate has a first surface coupled to the front surface of the semiconductor substrate. A redistribution layer is formed between the front surface of the semiconductor substrate and the second surface of the carrier substrate to route electrical signals between the imaging array and a second surface of the carrier substrate.

Abstract: The invention involves the integration of curved micro-mirrors over a photodiode active area (collection area) in a CMOS image sensor (CIS) process. The curved micro-mirrors reflect light that has passed through the collection area back into the photo diode. The curved micro-mirrors are best implemented in a backside illuminated device (BSI).

Abstract: The invention relates to a method of manufacturing a semiconductor device (10) with a field effect transistor, in which method a semiconductor body (1) of a semiconductor material is provided, at a surface thereof, with a source region (2) and a drain region (3) and with a gate region (4) between the source region (2) and the drain region (3), which gate region comprises a semiconductor region (4A) of a further semiconductor material that is separated from the surface of the semiconductor body (1) by a gate dielectric (5), and with spacers (6) adjacent to the gate region (4), for forming the source and drain regions (2,3), in which method the source region (2) and the drain region (3) are provided with a metal layer (7) which is used to form a compound (8) of the metal and the semiconductor material, and the gate region (4) is provided with a metal layer (7) which is used to form a compound (8) of the metal and the further semiconductor material.

Abstract: The present invention provides a method for processing a semiconductor device wherein a dielectric layer is partially converted into a silicon-oxy-nitride by incorporation of nitrogen atoms into the dielectric layer, which comprises a silicon oxide. Before the introduction of the nitrogen atoms into the dielectric layer, the dielectric layer is provided as a silicon oxide in which the atomic silicon to oxygen ration is greater than ½. In this way, MOS transistors are obtained with a high quality interface between the dielectric region and semiconductor substrate, and a dielectric region which is impermeable to impurity atoms from the gate region and which has a thickness which is substantially equal to the dielectric layer as deposited.