Improved pixel circuits are disclosed for high fill-factor large area imager systems using continuous (e.g., amorphous silicon) sensor layers. A first approach prevents crosstalk by ensuring that each pixel is not able to go into saturation. A second approach employs a cascode transistor to maintain the bias of the sensor contact at a constant potential regardless of illumination condition. These two approaches may be combined. A resistive film connecting the pixel contacts may be used in conjun...

A semiconductor device comprising a first insulation layer, a second insulation layer, a first barrier film, a second barrier film, a diffusion layer. The device further comprises an upper contact hole, a lower contact hole, and a contact plug. The upper contact hole penetrates the second insulation layer and has a bottom in the second barrier film. The bottom has a width greater than a trench made in the first insulation layer, as measured in a direction crossing the widthwise direction of the ...

The benefits of strained semiconductors are combined with silicon-on-insulator approaches to substrate and device fabrication.

A chalcogenide phase change memory cell has a substrate with a conductor line. The conductor line has a contact end. An insulating layer is located over the substrate and conductor line. An aperture is located in the insulating layer. The aperture extends to the substrate. A memory material is conformally located within the aperture. The memory material is in electrical contact with the contact end. A conductive layer is located over the memory material in the aperture.

A solid-state imaging device includes a two-dimensional array of photosensor sections on a semiconductor substrate, and a vertical transfer section including two-layer vertical transfer electrodes. The photosensor sections store signal charges generated by photoelectric conversion. The vertical transfer section reads signal charges from the photosensor sections and vertically transfers the read signal charges. The two-layer vertical transfer electrodes have first transfer electrode layers and se...

A group 3 5 compound semiconductor comprising an interface of two layers having lattice mismatch, an intermediate layer having a film thickness of 25 nm or more and a quantum well layer, in this order. The compound semiconductor has high crystallinity and high quality, and suitably used for a light emitting diode.

A semiconductor device and a manufacturing method thereof in which the peripheral length of an aperture and the mechanical strength of cylinders in a cell can be increased without changing the occupation rate of patterns in the cell. By forming a slit in the middle of each mask pattern so as not to expose parts of wafer, the aperture of the wafer becomes nearly cocoon-shaped with a constriction in the middle. Thereby, the peripheral length of the aperture can be increased without changing the oc...

A thin film transistor composed of: (a) a semiconductor layer including a thiophene compound, wherein the thiophene compound comprises one or more substituted thiophene units, one or more unsubstituted thiophene units, and optionally one or more divalent linkages; (b) a gate dielectric; and (c) a layer contacting the gate dielectric disposed between the semiconductor layer and the gate dielectric, wherein the layer comprises a substance comprising a fluorocarbon structure.

A thin film transistor array substrate includes a gate pattern on a substrate. The gate pattern includes a gate electrode, a gate line connected to the gate electrode, and a lower gate pad electrode connected to the gate line. A source/drain pattern includes a source electrode and a drain electrode, a data line connected to the source electrode, and a lower data pad electrode connected to the data line. A semiconductor pattern is formed beneath the source/drain pattern. A transparent electrode p...

A semiconductor package according to the present invention includes a metal can which receives in its interior space a MOSFET. The MOSFET so received is oriented such that its drain electrode is facing the bottom of the can and is electrically connected to the same by a layer of conductive epoxy or a solder or the like. The edges of the MOSFET so placed are spaced from the walls of the can. The space between the edges of the MOSFET and the walls of the can is filled with an insulating layer. A s...