An ESD protection apparatus includes a semiconductor substrate, a first gate structure, a first doping region, a second doping region and a third doping region. The semiconductor substrate has a doping well with a first conductivity one end of which is grounded. The first gate structure is disposed on the doping well. The first doping region having a second conductivity, is disposed in the doping well and adjacent to the first gate structure, and is electrically connected to a pad. The second doping region having the second conductivity is disposed in the doping well and adjacent to the first gate structure. The third doping region having the first conductivity is disposed in the doping well and forms a P/N junction interface with the second doping region, wherein the second doping region and the third doping region respectively have a doping concentration substantially greater than that of the doping well.

A transistor including a semiconductor, a first conductor, a second conductor, a third conductor, a first insulator, and a second insulator is manufactured by forming a hard mask layer including a fourth conductor over the second insulator, a third insulator over the fourth conductor, forming an opening portion in the second insulator with the hard mask layer as the mask, eliminating the hard mask layer by forming the opening portion, and forming the first insulator and the first conductor in the opening portion.

A semiconductor structure includes an access transistor, a first memory device connected to a first side of the access transistor, and a second memory device connected to a second side of the access transistor. In some embodiments, the first memory device is connected to a first end of a first source/drain region of the access transistor and the second memory device is connected to a second end of the first source/drain region of the access transistor. In other embodiments, the first memory device is connected to a first source/drain region of the access transistor and the second memory device is connected to a second source/drain region of the access transistor.

By applying an AC pulse to a gate of a transistor which easily deteriorates, a shift in threshold voltage of the transistor is suppressed. However, in a case where amorphous silicon is used for a semiconductor layer of a transistor, the occurrence of a shift in threshold voltage naturally becomes a problem for a transistor which constitutes a part of circuit that generates an AC pulse. A shift in threshold voltage of a transistor which easily deteriorates and a shift in threshold voltage of a turned-on transistor are suppressed by signal input to a gate electrode of the transistor which easily deteriorates through the turned-on transistor. In other words, a structure for applying an AC pulse to a gate electrode of a transistor which easily deteriorates through a transistor to a gate electrode of which a high potential (VDD) is applied, is included.

An integrated circuit includes a first time delay circuit, a second time delay circuit, and a master-slave flip-flop having a gated input circuit and a transmission gate. The transmission gate is configured to receive the first clock signal and the second clock signal to control a transmission state of the transmission gate. The gated input circuit is configured to have an input transmission state controlled by the third clock signal at the second output of the second time delay circuit. The second time delay circuit further includes a second gate-conductor and a second gate via-connector in direct contact with the second gate-conductor. The second gate-conductor intersects a first-type active region structure and a second-type active region structure in a second area, and wherein at least a portion of the second gate via-connector is atop the second-type active region structure

A method of forming a split gate memory cell structure using a substrate includes forming a gate stack comprising a select gate and a dielectric portion overlying the select gate. A charge storage layer is formed over the substrate including over the gate stack. A first sidewall spacer of conductive material is formed along a first sidewall of the gate stack extending past a top of the select gate. A second sidewall spacer of dielectric material is formed along the first sidewall on the first sidewall spacer. A portion of the first sidewall spacer is silicided using the second sidewall spacer as a mask whereby silicide does not extend to the charge storage layer.

A semiconductor substrate having a first main surface and a transistor cell includes a drift region, a body region between the drift region and the first main surface, an active trench at the first main surface extending into the drift region, a gate insulating layer at sidewalls and a bottom side of the active trench, a gate conductive layer in the active trench, a source region in the body region, and adjacent to the active trench, a body trench at the first main surface extending into the drift region, the body trench being adjacent to the body region and to the drift region, an insulating layer at sidewalls and at a bottom side of the body trench, the insulating layer being asymmetric with respect to an axis extending perpendicular to the first main surface at a center of the body trench, and a conductive layer in the body trench.

By applying an AC pulse to a gate of a transistor which easily deteriorates, a shift in threshold voltage of the transistor is suppressed. However, in a case where amorphous silicon is used for a semiconductor layer of a transistor, the occurrence of a shift in threshold voltage naturally becomes a problem for a transistor which constitutes a part of circuit that generates an AC pulse. A shift in threshold voltage of a transistor which easily deteriorates and a shift in threshold voltage of a turned-on transistor are suppressed by signal input to a gate electrode of the transistor which easily deteriorates through the turned-on transistor. In other words, a structure for applying an AC pulse to a gate electrode of a transistor which easily deteriorates through a transistor to a gate electrode of which a high potential (VDD) is applied, is included.

An apparatus is provided which comprises: a stack of transistors of a same conductivity type, the stack including a first transistor and a second transistor coupled in series and having a common node; and a feedback transistor of the same conductivity type coupled to the common node and a gate terminal of the first transistor of the stack.

A novel semiconductor device is provided. A memory cell MC has a function of supplying a signal corresponding to the product of first data and second data to a wiring BX, and also has a function of supplying a signal corresponding to the product of the first data and third data to a wiring BY. The wiring BX is connected to a plurality of memory cells MC. Each of the plurality of memory cells MC outputs a signal corresponding to the result of the product operation to the wiring BX. The wiring BX has a function of transmitting a signal corresponding to the sum of these signals. The wiring BY is connected to a plurality of memory cells MC. Each of the plurality of memory cells MC outputs a signal corresponding to the result of the product operation to the wiring BY. The wiring BY has a function of transmitting a signal corresponding to the sum of these signals.