Abstract: A photoconductor assembly includes a substrate formed of an undoped and single-crystal semiconductor material that is configured to absorb electromagnetic energy, a plurality of electrodes arranged normal to the substrate, and a power supply that applies a voltage to the electrodes for modulating the electromagnetic energy through the substrate.

Abstract: The present invention provides an ultra-violet light sensing device. The ultra-violet light sensing device includes a first conductivity type substrate, a second conductivity type region, and a first conductivity type high density region. The first conductivity type substrate includes a light incident surface. The second conductivity type region is disposed in the first conductivity type substrate and adjacent to the light incident surface. The first conductivity type high density region is disposed under the second conductivity type region. The present invention also provides another ultra-violet light sensing device, which further includes a first conductivity type high density shallow region which is sandwiched between the light incident surface and the second conductivity type region. Manufacturing methods for these ultra-violet light sensing devices are also disclosed in the present invention.

Abstract: A sensor device (100, 2800) for detecting particles, the sensor device (100, 2800) comprising a substrate (102), a first doped region (104) formed in the substrate (102) by a first dopant of a first type of conductivity, a second doped region (106, 150) formed in the substrate (102) by a second dopant of a second type of conductivity which differs from the first type of conductivity, a depletion region (108) at a junction between the first doped region (104) and the second doped region (106, 150), a sensor active region (110) adapted to influence a property of the depletion region (108) in the presence of the particles, and a detection unit (112) adapted to detect the particles based on an electric measurement performed upon application of a predetermined reference voltage between the first doped region (104) and the second doped region (106, 150), the electric measurement being indicative of the presence of the particles in the sensor active region (110).

Abstract: GaN-based heterojunction field effect transistor (HFET) sensors are provided with engineered, functional surfaces that act as pseudo-gates, modifying the drain current upon analyte capture. In some embodiments, devices for sensing nitric oxide (NO) species in a NO-containing fluid are provided which comprise a semiconductor structure that includes a pair of separated GaN layers and an AlGaN layer interposed between and in contact with the GaN layers. Source and drain contact regions are formed on one of the GaN layers, and an exposed GaN gate region is formed between the source and drain contact regions for contact with the NO-containing fluid. The semiconductor structure most preferably is formed on a suitable substrate (e.g., SiC). An insulating layer may be provided so as to cover the semiconductor structure. The insulating layer will have a window formed therein so as to maintain exposure of the GaN gate region and thereby allow the gate region to contact the NO-containing fluid.

Abstract: An optical semiconductor device that performs photoelectric conversion, comprising: a semiconductor substrate that includes (i) a first conductivity-type semiconductor region, (ii) a second conductivity-type semiconductor region that is positioned on the first conductivity-type semiconductor region and has a light receiving surface, and (iii) a first conductivity-type contact region that penetrates, from an upper surface of the second conductivity-type semiconductor region, the second conductivity-type semiconductor region so as to be in contact with the first conductivity-type semiconductor region; an electrode pair for drawing current obtained by performing photoelectric conversion of light incident on the light receiving surface, the electrode pair being composed of (i) a first electrode that is positioned on the first conductivity-type contact region and (ii) a second electrode that is positioned on the second conductivity-type semiconductor region so as to be separated from the first electrode; an insula

Abstract: Ultra thin photodiode array structures and fabrication methods are disclosed. The back illuminated or front illuminated photodiode arrays have the active portion fabricated in a semiconductor layer which may be bonded to a supporting substrate layer. The active portion of semiconductor layer may comprise epitaxially grown layer. The isolation regions between pixels of an array may span the epitaxial layer and a semiconductor layer. Electrical contacts to the diodes are made through the bonded substrate or a portion of active layer. Methods of fabrication include steps to form a photodiode array of this type as well as steps to bond this array to supporting substrates. In some embodiments, supporting substrates are temporarily bonded for support of the methods of processing.

Abstract: A solid-state image pickup device 10 has an arrangement in which a second conductivity type semiconductor region 14 is formed on the surface of a first conductivity type electric charge accumulation region 13 of a light-receiving sensor portion, a shallow trench isolation layer 20 formed of an insulating layer is buried into a trench formed on a semiconductor substrate 11, the shallow trench isolation layer 20 is composed of an upper wide portion 21 and a lower narrow portion 22 and a second conductivity type semiconductor region 23 is formed around the lower narrow portion 22 of the shallow trench isolation layer 20. The solid-state image pickup device can suppress the occurrence of a dark current and a white spot, it can produce an image with high image quality and it can sufficiently maintain a sufficiently large amount of electric charges that can be handled by the light-receiving sensor portion.