Abstract: A trench is formed in the surface of a provided semiconductor body. An oxide is deposited in the trench and a cap is deposited on the oxide, wherein the combination of the cap and the oxide impart a mechanical stress on the semiconductor body.

Abstract: Structures and methods of forming self aligned silicided contacts are disclosed. The structure includes a gate electrode disposed over an active area, a liner disposed over the gate electrode and at least a portion of the active area, an insulating layer disposed over the liner. A first contact plug is disposed in the insulating layer and the liner, the first contact plug disposed above and in contact with a portion of the active area, the first contact plug including a first conductive material. A second contact plug is disposed in the insulating layer and the liner, the second contact plug disposed above and in contact with a portion of the gate electrode, the second contact plug includes the first conductive material. A contact material layer is disposed in the active region, the contact material layer disposed under the first contact plug and includes the first conductive material.

Abstract: Resistors, semiconductor devices, and methods of manufacture thereof are disclosed. In one embodiment, a method of fabricating a resistor includes forming a semiconductive material over a workpiece, and patterning at least the semiconductive material, forming a gate of a transistor in a first region of the workpiece and forming a resistor in a second region of the workpiece. At least one substance is implanted into the semiconductive material of the gate of the transistor or the resistor so that the semiconductive material is different for the gate of the transistor and the resistor.

Abstract: A trench is formed in the surface of a provided semiconductor body. An oxide is deposited in the trench and a cap is deposited on the oxide, wherein the combination of the cap and the oxide impart a mechanical stress on the semiconductor body.

Abstract: Methods of forming features and structures thereof are disclosed. In one embodiment, a method of forming a feature includes forming a first material over a workpiece, forming a first pattern for a lower portion of the feature in the first material, and filling the first pattern with a sacrificial material. A second material is formed over the first material and the sacrificial material, and a second pattern for an upper portion of the feature is formed in the second material. The sacrificial material is removed. The first pattern and the second pattern are filled with a third material.

Abstract: Stress-inducing structures, methods, and materials are disclosed. In one embodiment, an isolation region includes an insulating material in a lower portion of a trench formed in a workpiece and a stress-inducing material disposed in a top portion of the trench over the insulating material.

Abstract: A trench is formed in the surface of a provided semiconductor body. An oxide is deposited in the trench and a cap is deposited on the oxide, wherein the combination of the cap and the oxide impart a mechanical stress on the semiconductor body.

Abstract: The prevention of active area loss in the STI model is disclosed which results in an improved device performance in devices manufactured according to the process flow. The process generally shared among the multiple various embodiments inverts the current conventional STI structure towards a process flow where an insulator is patterned with tapered trenches. A segregation layer is formed beneath the surface of the insulator in the tapered trenches. The tapered trenches are then filled with a semiconductor material which is further processed to create a number of active devices. Therefore, the active devices are created in patterned dielectric instead of the STI being created in the semiconductor substrate of the active devices.

Abstract: Copper integration in the FEOL stage is disclosed for a preliminary semiconductor device by forming a recess in a substrate of the device, the recess having a bottom surface and sidewall surfaces, depositing a barrier layer having about a 100% step coverage on the sidewall surfaces and the bottom surface, and depositing copper into the recess over the barrier layer to form a contact providing electrical connection to the preliminary semiconductor device.

Abstract: Structures and methods of forming self aligned silicided contacts are disclosed. The structure includes a gate electrode disposed over an active area, a liner disposed over the gate electrode and at least a portion of the active area, an insulating layer disposed over the liner. A first contact plug is disposed in the insulating layer and the liner, the first contact plug disposed above and in contact with a portion of the active area, the first contact plug including a first conductive material. A second contact plug is disposed in the insulating layer and the liner, the second contact plug disposed above and in contact with a portion of the gate electrode, the second contact plug includes the first conductive material. A contact material layer is disposed in the active region, the contact material layer disposed under the first contact plug and includes the first conductive material.

Abstract: A trench is formed in the surface of a provided semiconductor body. An oxide is deposited in the trench and a cap is deposited on the oxide, wherein the combination of the cap and the oxide impart a mechanical stress on the semiconductor body.

Abstract: A method of making a semiconductor interconnect is disclosed. A semiconductor body on which a transistor comprising a doped region is formed is provided. A dielectric region is formed over the doped region, and a contact hole is formed in the dielectric to expose the doped region. The contact hole is cleaned and a first layer of metal is formed over a bottom and sidewalls of the contact hole. The first layer of metal is thinned so that the thickness of the first layer of metal on the sidewalls is made more uniform. A barrier is formed over the first layer of metal and the contact hole is filled with conductive material.

Abstract: Dielectric layers are formed on a substrate by performing Subatmospheric Chemical Vapor Deposition (SACVD) of ozone-tetraethoxysilane (O3-TEOS) to form a layer of O3-TEOS on the substrate, and treating the layer of O3-TEOS with ultraviolet (UV) radiation. The UV radiation treatment can increase the tensile stress in the O3-TEOS layer by reducing the amount of water in the layer. Moreover, the UV treatment may also reduce the amount of silanol in the O3-TEOS layer, which can also increase reliability of the device.

Abstract: Methods of fabricating isolation regions of semiconductor devices and structures thereof are disclosed. In a preferred embodiment, a semiconductor device includes a workpiece and at least one trench formed in the workpiece. The at least one trench includes sidewalls, a bottom surface, a lower portion, and an upper portion. A first liner is disposed over the sidewalls and the bottom surface of the at least one trench. A second liner is disposed over the first liner in the lower portion of the at least one trench. A first insulating material is disposed over the second liner in the lower portion of the at least one trench. A second insulating material is disposed over the first insulating material in the upper portion of the at least one trench. The first liner, the second liner, the first insulating material, and the second insulating material comprise an isolation region of the semiconductor device.

Abstract: Provided is a method of manufacturing a semiconductor device with enhanced electrical characteristics. The method includes disposing a substrate on a substrate support in a process chamber, pre-heating the substrate on the substrate support adjusted to a temperature from 300 to 400° C. for 60 seconds or more, forming a silicon protective layer on the substrate by supplying a silicon source gas into the process chamber and heating the substrate on the substrate support adjusted to a temperature from 300 to 400° C. for 10 seconds or more, and forming a tungsten layer on the silicon protective layer.

Abstract: Provided is a method of manufacturing a semiconductor device with enhanced electrical characteristics. The method includes disposing a substrate on a substrate support in a process chamber, pre-heating the substrate on the substrate support adjusted to a temperature from 300 to 400° C. for 60 seconds or more, forming a silicon protective layer on the substrate by supplying a silicon source gas into the process chamber and heating the substrate on the substrate support adjusted to a temperature from 300 to 400° C. for 10 seconds or more, and forming a tungsten layer on the silicon protective layer.