An integrated circuit device having a body bias voltage mechanism. The integrated circuit comprises a resistive structure disposed therein for selectively coupling either a body bias voltage or a power supply voltage to biasing wells. A first pad for coupling with a first externally disposed pin can optionally be provided. The first pad is for receiving an externally applied body bias voltage. Circuitry for producing a body bias voltage can be coupled to the first pad for coupling a body bias voltage to a plurality of biasing wells disposed on the integrated circuit device. If a body bias voltage is not provided, the resistive structure automatically couples a power supply voltage to the biasing wells. The power supply voltage may be obtained internally to the integrated circuit.

The present disclosure provides a thin film transistor, a method for manufacturing the same, a thin film transistor assembly, an array substrate and a display apparatus. The thin film transistor comprises: a substrate; a gate electrode, a gate insulation portion, a semiconductor portion, a source electrode and a drain electrode, the gate insulation portion separating the semiconductor portion from the gate electrode, and the source electrode and the drain electrode being connected to the semiconductor portion, wherein a projection of the gate electrode onto the substrate and that of the semiconductor portion onto the substrate are not overlapped with each other.

A driver IC for driving a display panel, a display device and a method for driving the driver IC are provided. The driver IC is provided with N pins corresponding to N signal transmission lines of the display panel respectively. Each pin is connected to one corresponding signal transmission line through one transmission wire. The N pins include a first pin and a second pin. The transmission wires include a first transmission wire connected to the first pin and a second transmission wire connected to the second pin and having a length less than the first transmission wire. The driver IC includes a signal generation module configured to generate N driving signals. The N driving signals include a first driving signal corresponding to the first pin and a second driving signal corresponding to the second pin and having a current intensity less than the first driving signal.

A semiconductor structure less affected by stress and a method for forming the same are provided. The semiconductor structure includes a semiconductor chip. Stress-sensitive circuits are substantially excluded out of an exclusion zone to reduce the effects of the stress to the stress-sensitive circuits. The stress-sensitive circuits include analog circuits. The exclusion zone preferably includes corner regions of the semiconductor chip, wherein the corner regions preferably have a diagonal length of less than about one percent of the diagonal length of the semiconductor chip. The stress-sensitive analog circuits preferably include devices having channel lengths less than about five times the minimum channel length.

The present disclosure provides one embodiment of an IC method that includes receiving an IC design layout, which has a plurality of main features and a plurality of space blocks. The IC method also includes calculating an optimized block dummy density ratio r.sub.0 to optimize a uniformity of pattern density (UPD), determining a target block dummy density ratio R, determining size, pitch and type of a non-printable dummy feature, generating a pattern for dummy features and adding the dummy features in the IC design layout.

A nanofluidic structure including a semiconductor substrate and a dielectric layer positioned above and in contact with the semiconductor substrate. A first reservoir and a second reservoir are defined by the semiconductor substrate and the dielectric layer. The second reservoir is spaced apart from the first reservoir. Bottom passage fins protrude from the semiconductor substrate and extend from the first reservoir to the second reservoir. Top passage fins, above and spaced apart from the bottom passage fins, extend from the first reservoir to the second reservoir. Nanofluidic passages between the top and bottom fins connect the first reservoir and the second reservoir. Each of the nanofluidic passages includes a bottom wall, a top wall and sidewalls. The bottom wall is defined by a respective bottom passage fin. The top wall is defined by a respective top passage fin. The sidewalls are defined by the dielectric layer.

A TFT display device and a method for producing the device are disclosed. The TFT display device includes: a first metal layer, on which a first silicon nitride film is deposited; a second metal layer deposited on the first silicon nitride film and etched to form a pattern, wherein a second silicon nitride film is deposited on the second metal film; and a via hole, wherein the first metal layer and/or the second metal layer are disconnected in the overlapping region. The first silicon nitride layer and the second silicon nitride layer are etched to form the via hole On the disconnected position, and an ITO conductive film is deposited to electrically connect the disconnected position. According to the present invention, by means of the above-mentioned way, the TFT display device will have less damage by ESD. The yield rate of the product is increased, and the product competitiveness is enhanced.

A method for designing a semiconductor device includes establishing boundary conditions for a layout of each cell of a plurality of cells, wherein each cell has a plurality of features, and boundary conditions are established based on a proximity of each feature to a cell boundary of a corresponding cell. The method includes determining whether the layout of each cell is colorable based on a number of masks used to manufacture a layer of the semiconductor device, a minimum spacing requirement for the plurality of features, and the established boundary conditions. The method includes forming a layout of the layer of the semiconductor device by abutting a first cell of the plurality of cells with a second cell of the plurality of cells. The method includes reporting the layout of the layer of the semiconductor device as colorable without analyzing the layout of the layer of the semiconductor device.

According to some embodiments of the invention, a substrate doped with a P type impurity is provided. An N type impurity is doped into the substrate to divide the substrate into a P type impurity region and an N type impurity region. Active patterns having a first pitch are formed in the P type and N type impurity regions. Gate patterns having a second pitch are formed on the active patterns in a direction substantially perpendicular to the active patterns. Other embodiments are described and claimed.

Methods for extreme ultraviolet (EUV) mask defect mitigation by using multi-patterning lithography techniques. In one exemplary embodiment, a method for fabricating an integrated circuit including identifying a position of a defect in a first EUV photolithographic mask, the photolithographic mask including a desired pattern and transferring the desired pattern to a photoresist material disposed on a semiconductor substrate. Transferring the desired pattern further transfers an error pattern feature to the photoresist material as a result of the defect in the first EUV photolithographic mask. The method further includes, using a second photolithographic mask, transferring a trim pattern to the photoresist material, wherein the trim pattern removes the error pattern feature from the photoresist material.