A switched-capacitor DC-to-DC converter includes a logic cell and a capacitor cell vertically overlapping with the logic cell. The logic cell has a plurality of active elements disposed over a first substrate. The capacitor cell has a capacitor over a second substrate. A first interlayer insulation layer disposed over the first substrate is bonded to a second interlayer insulation layer disposed over the second substrate. A first through via connected to any one of interconnection patterns of the logic cell and a second through via connected to a lower electrode pattern of the capacitor cell are connected to each other through a first external circuit pattern. A third through via connected to an upper electrode pattern of the capacitor cell and a fourth through via connected to another one of the interconnection patterns of the logic cell are connected to each other through a second external circuit pattern.

An integrated circuit contains a logic MOS transistor and a memory MOS transistor of a same polarity. The logic MOS transistor has a logic channel stop layer. The memory MOS transistor has a memory channel stop layer. An average dopant density of the memory channel stop layer is higher than an average dopant density of the logic channel stop layer. The integrated circuit is formed by forming a global mask which exposes both the logic and memory MOS transistors. A global channel stop dose of dopants is implanted in the logic and memory MOS transistors. A memory mask is formed which exposes the memory MOS transistor and covers the logic MOS transistor. A memory channel stop dose of dopants of the same polarity is implanted into the memory MOS transistors. The memory channel stop dose of dopants are blocked from the logic MOS transistors.

Gate structures formed from substantially rectangular shaped gate structure layout shapes positioned on a gate horizontal grid having at least seven gate gridlines within a region. A first-metal layer including first-metal structures formed from substantially rectangular shaped first-metal structure layout shapes is formed above top surfaces of the gate structures within the region. The first-metal structure layout shapes are positioned on a first-metal vertical grid having at least eight first-metal gridlines. At least six contact structures are formed from substantially rectangular shaped contact structure layout shapes in physical and electrical contact with corresponding ones of at least six of the gate structures. A total number of first-transistor-type-only gate structures equals a total number of second-transistor-type-only gate structures within the region. At least four transistors of a first transistor type and at least four transistors of a second transistor type collectively form part of a logic circuit within the region.

Gate structures are positioned within a region in accordance with a gate horizontal grid that includes at least seven gate gridlines separated from each other by a gate pitch of less than or equal to about 193 nanometers. Each gate structure has a substantially rectangular shape with a width of less than or equal to about 45 nanometers and is positioned to extend lengthwise along a corresponding gate gridline. Each gate gridline has at least one gate structure positioned thereon. A first-metal layer is formed above top surfaces of the gate structures within the region and includes first-metal structures positioned in accordance with a first-metal vertical grid that includes at least eight first-metal gridlines. Each first-metal structure has a substantially rectangular shape and is positioned to extend along a corresponding first-metal gridline. At least six contact structures of substantially rectangular shape contact the at least six gate structures.

A transistor with stable electrical characteristics is provided. Provided is a method for manufacturing a semiconductor device that includes, over a substrate, an oxide semiconductor, a first conductor, a first insulator, a second insulator, and a third insulator. The oxide semiconductor is over the first insulator. The second insulator is over the oxide semiconductor. The third insulator is over the second insulator. The first conductor is over the third insulator. The oxide semiconductor has a first region and a second region. To form the first region, ion implantation into the oxide semiconductor is performed using the first conductor as a mask, and then hydrogen is added to the oxide semiconductor using the first conductor as a mask.

One aspect of this disclosure is a power amplifier module that includes a power amplifier configured to provide a radio frequency signal at an output, an output matching network coupled to the output of the power amplifier and configured to provide impedance matching at a fundamental frequency of the radio frequency signal, and a harmonic termination circuit coupled to the output of the power amplifier. The power amplifier is included on a power amplifier die. The output matching network can include a first circuit element electrically connected to an output of the power amplifier by way of a pad on a top surface of a conductive trace, in which the top surface has an unplated portion between the pad the power amplifier die. The harmonic termination circuit can include a second circuit element. The first and second circuit elements can have separate electrical connections to the power amplifier die. Other embodiments of the module are provided along with related methods and components thereof.

A method for fabricating semiconductor device includes the steps of: providing a substrate, wherein the substrate comprises a first region and a second region; forming a high-k dielectric layer on the first region and the second region; forming a first bottom barrier metal (BBM) layer on the high-k dielectric layer of the first region and the second region; forming a stop layer on the first region and the second region; removing the stop layer on the second region; and forming a second BBM layer on the first region and the second region.

Gate structures are positioned within a region in accordance with a gate horizontal grid that includes at least seven gate gridlines separated from each other by a gate pitch of less than or equal to about 193 nanometers. Each gate structure has a substantially rectangular shape with a width of less than or equal to about 45 nanometers and is positioned to extend lengthwise along a corresponding gate gridline. Each gate gridline has at least one gate structure positioned thereon. A first-metal layer is formed above top surfaces of the gate structures within the region and includes first-metal structures positioned in accordance with a first-metal vertical grid that includes at least eight first-metal gridlines. Each first-metal structure has a substantially rectangular shape and is positioned to extend along a corresponding first-metal gridline. At least six contact structures of substantially rectangular shape contact the at least six gate structures.

A method of fabricating a vertical field effect transistor including forming a first recess in a substrate; epitaxially growing a first drain from the first bottom surface of the first recess; epitaxially growing a second drain from the second bottom surface of a second recess formed in the substrate; growing a channel material epitaxially on the first drain and the second drain; forming troughs in the channel material to form one or more fin channels on the first drain and one or more fin channels on the second drain, wherein the troughs over the first drain extend to the surface of the first drain, and the troughs over the second drain extend to the surface of the second drain; forming a gate structure on each of the one or more fin channels; and growing sources on each of the fin channels associated with the first and second drains.

The disclosed technology generally relates to semiconductor devices, and more particularly to transistor devices comprising multiple channels. In one aspect, a method of fabricating a transistor device comprises forming on the substrate a plurality of vertically repeating layer stacks each comprising a first layer, a second layer and a third layer stacked in a predetermined order, wherein each of the first, second and third layers is formed of silicon, silicon germanium or germanium and has a different germanium concentration compared to the other two of the first, second and third layers. The method additionally includes selectively removing the first layer with respect to the second and third layers from each of the layer stacks, such that a gap interposed between the second layer and the third layer is formed in each of the layer stacks. The method further includes selectively removing the second layer from each of the layer stacks with respect to the third layer, wherein removing the second layer comprises at least partially removing the second layer through the gap, thereby defining the channels comprising a plurality of vertically arranged third layers.