A power amplifier module includes a power amplifier including a GaAs bipolar transistor having a collector, a base abutting the collector, and an emitter, the collector having a doping concentration of at least about 310.sup.16 cm.sup.3 at a junction with the base, the collector also having at least a first grading in which doping concentration increases away from the base; and an RF transmission line driven by the power amplifier, the RF transmission line including a conductive layer and finish plating on the conductive layer, the finish plating including a gold layer, a palladium layer proximate the gold layer, and a diffusion barrier layer proximate the palladium layer, the diffusion barrier layer including nickel and having a thickness that is less than about the skin depth of nickel at 0.9 GHZ. Other embodiments of the module are provided along with related methods and components thereof.

A semiconductor apparatus includes a flat portion disposed in a predetermined region containing a central depth position of a semiconductor substrate, between a fist peak disposed in an upper surface side of the semiconductor substrate and a second peak disposed in a lower surface side of the semiconductor substrate, and having a substantially flat concentration higher than a bulk donor concentration in a donor concentration distribution in a depth direction of a semiconductor substrate. The entire oxygen chemical concentration between the first peak and the second peak ranges from 310.sup.15 atoms/cm.sup.3 to 210.sup.18 atoms/cm.sup.3.

An integrated circuits (IC) includes a standard cell array and a SRAM cell array. The standard cell array includes standard cells having first P-type transistors arranged in a first column of the standard cell array and a first fin structure shared by the first P-type transistors. The SRAM cell array includes SRAM cells having second P-type transistors arranged in a second column of the SRAM cell array and second fin structures arranged in the second column. Each of the second fin structures is shared by two adjacent second P-type transistors respectively disposed in two adjacent SRAM cells. A material of the first fin structure is different from a material of the second fin structures. A dimension of the first fin structure along the first column is greater than a dimension of each of the second fin structures along the second column.

An integrated circuits (IC) includes a standard cell array and a SRAM cell array. The standard cell array includes standard cells having first P-type transistors arranged in a first column of the standard cell array and a first fin structure shared by the first P-type transistors. The SRAM cell array includes SRAM cells having second P-type transistors arranged in a second column of the SRAM cell array and second fin structures arranged in the second column. Each of the second fin structures is shared by two adjacent second P-type transistors respectively disposed in two adjacent SRAM cells. A material of the first fin structure is different from a material of the second fin structures. A dimension of the first fin structure along the first column is greater than a dimension of each of the second fin structures along the second column.

A first impurity diffusion region is provided within a semiconductor substrate, a second impurity diffusion region is provided within the first impurity diffusion region, a third impurity diffusion region is provided within the second impurity diffusion region, a first portion of a fourth impurity diffusion region is provided within the second impurity diffusion region so as to be spaced from the third impurity diffusion region, and a second portion of the fourth impurity diffusion region is provided in a third portion of the first impurity diffusion region on a side of a surface of the semiconductor substrate, a first contact is provided so as to be in contact with the second portion, the first contact and the third portion overlap in plan view, and a first power supply is connected to the third impurity diffusion region.

Methods and systems for power semiconductor devices integrating multiple trench transistors on a single chip. Multiple power transistors (or active regions) are paralleled, but one transistor has a lower threshold voltage. This reduces the voltage drop when the transistor is forward-biased. In an alternative embodiment, the power device with lower threshold voltage is simply connected as a depletion diode, to thereby shunt the body diodes of the active transistors, without affecting turn-on and ON-state behavior.

A semiconductor component includes a semiconductor body of a first conduction type and a metal layer on the semiconductor body, wherein the metal layer forms with the semiconductor body a Schottky contact along a contact surface. A doping concentration of the first conduction type on the contact surface varies along a direction of the contact surface.

A method of forming a semiconductor includes a providing a termination trench and an active trench within a semiconductor layer. The active trench is configured to be at a shallower depth than the termination trench to provide a trench depth difference. The selected trench depth difference in combination with one or more of the dopant concentration of the semiconductor layer, the thickness of the semiconductor layer, active trench width to termination trench width, and/or dopant profile of the semiconductor layer provide a semiconductor device having improved performance characteristics.

A MOSFET having a stacked-gate super-junction design and novel termination structure. At least some illustrative embodiments of the device include a conductive (highly-doped with dopants of a first conductivity type) substrate with a lightly-doped epitaxial layer. The volume of the epitaxial layer is substantially filled with a charge compensation structure having vertical trenches forming intermediate mesas. The mesas are moderately doped via the trench sidewalls to have a second conductivity type, while the mesa tops are heavily-doped to have the first conductivity type. Sidewall layers are provided in the vertical trenches, the sidewall layers being a moderately-doped semiconductor of the first conductivity type. The shoulders of the sidewall layers are recessed below the mesa top to receive an overlying gate for controlling a channel between the mesa top and the sidewall layer. The mesa tops are coupled to a source electrode, while a drain electrode is provided on the back side of the substrate.

A semiconductor device includes a substrate having an upper surface, a plurality of active fins on the substrate, a gate electrode crossing the plurality of active fins, and at each side of the gate electrode, a source/drain region on the plurality of active fins. The source/drain region may include a plurality of first regions extending from the active fins, and a second region between each of the plurality of first regions. The second region may have a second germanium concentration greater than the first germanium concentration. The source/drain region may be connected to a contact plug, and may have a top surface that has a wave shaped, or curved surface. The top surface may have a larger surface area than a top surface of the contact plug.