Abstract: According to the embodiments to the present disclosure, the process of making a dual strained channel semiconductor device includes integrating strained Si and compressed SiGe with trench isolation for achieving a simultaneous NMOS and PMOS performance enhancement. As described herein, the integration of NMOS and PMOS can be implemented in several ways to achieve NMOS and PMOS channels compatible with shallow trench isolation.

Abstract: A semiconductor device has: a semiconductor substrate having a pair of current input/output regions via which current flows; an insulating film formed on the semiconductor substrate and having a gate electrode opening; and a mushroom gate electrode structure formed on the semiconductor substrate via the gate electrode opening, the mushroom gate electrode structure having a stem and a head formed on the stem, the stem having a limited size on the semiconductor substrate along a current direction and having a forward taper shape upwardly and monotonically increasing the size along the current direction, the head having a size expanded stepwise along the current direction, and the stem contacting the semiconductor substrate in the gate electrode opening and riding the insulating film near at a position of at least one of opposite ends of the stem along the current direction.

Abstract: A method for making a semiconductor device is described. That method comprises forming a dielectric layer on a substrate, forming a trench within the dielectric layer, and forming a high-k gate dielectric layer within the trench. After forming a first metal layer on the high-k gate dielectric layer, a second metal layer is formed on the first metal layer. At least part of the second metal layer is removed from above the dielectric layer using a polishing step, and additional material is removed from above the dielectric layer using an etch step.

Abstract: The objective of this invention is to provide a semiconductor device and its manufacturing method with which the offset can be kept fixed even in high breakdown voltage MOS transistors, and that can accommodate high voltages for high breakdown voltage MOS transistors and miniaturization of MOS transistors for low voltage drive. Its constitution provides for inner side wall insulating films 14 and 24 and outer side wall insulating films 16 and 26 formed at both sides of the gate electrodes 12 and 22 in both high breakdown voltage transistor TR2 and transistor TR1 for low voltage drive, and heavily doped region 27 is formed in breakdown voltage transistor TR2 using both inner side wall insulating film 24 and outer side wall insulating film 26 as masks so that offset D2 is controlled by the combined widths of the two side wall insulating films. In transistor TR1 for low voltage drive, heavily doped region 15 is formed using only inner side wall insulating film 14 as the mask, and offset d1 is controlled.

Abstract: A method for manufacturing an integrated circuit that has a plurality of semiconductor devices including an n-type field effect transistor and a p-type field effect transistor. This method involves depositing oxide fill on the n-type transistor and the p-type transistor and chemical/mechanical polishing the deposited oxide fill such that a gate stack of the n-type transistor and a gate stack of the p-type transistor, which each have spacers which are surrounded with oxide. The method further involves etching a portion of the polysilicon from a gate of the p-type field effect transistor, depositing a low resistance material (e.g., Co, Ni, Ti, or other similar metals) on the n-type field effect transistor and the p-type field effect transistor, and heating the integrated circuit such that the deposited material reacts with the polysilicon of the n-type transistor and the polysilicon of the p-type transistor to form silicide.

Abstract: A method of forming layers, in the same device material, with different thickness or layer height in a semiconductor device comprises forming device material layer or gate electrode layer disposable parts in selected regions of the device layer. The disposable parts can be formed by doping the selected regions to the desired depth d. The as-deposited thickness t of this device layer can be adjusted or modulated after the patterning of the individual devices by removing the disposable parts.