Various embodiments of the present application are directed towards a semiconductor-on-insulator (SOI) substrate. The SOI substrate includes a handle substrate; a device layer overlying the handle substrate; and an insulator layer separating the handle substrate from the device layer. The insulator layer meets the device layer at a first interface and meets the handle substrate at a second interface. The insulator layer comprises a getter material having a getter concentration profile. The handle substrate contains getter material and has a handle getter concentration profile. The handle getter concentration profile has a peak at the second interface and a gradual decline beneath the second interface until reaching a handle getter concentration.

A semiconductor device structure is provided. The semiconductor device structure includes a fin structure formed over a semiconductor substrate and a gate structure formed across the fin structure. The semiconductor device structure also includes an isolation feature over a semiconductor substrate and below a portion of the gate structure and two spacer elements respectively formed over a first sidewall and a second sidewall of the gate structure. In addition, the first sidewall is opposite to the second sidewall and the two spacer elements have hydrophobic surfaces respectively facing the first sidewall and the second sidewall, and the gate structure includes a gate dielectric layer and a gate electrode layer separating the gate dielectric layer from the hydrophobic surfaces of the two spacer elements.

A Field Effect Transistor (FET) device and a method for manufacturing it are disclosed. The FET device contains a graphene layer, a composite gate dielectric layer disposed above the graphene layer, wherein the composite gate layer is passivated with fluorine, and a metal gate disposed above the composite gate dielectric layer. The method disclosed teaches how to manufacture the FET device.

A semiconductor device structure is provided. The semiconductor device structure includes first and second gate spacers formed over a semiconductor substrate, longitudinally extending along a first direction, and separated from each other by a gate electrode layer. A first insulating layer longitudinally extends along a second direction to pass through the gate electrode layer and the first and second gate spacers. A gate dielectric layer has a top surface covered by the gate electrode layer. The top width of the gate dielectric layer is less than that of the gate electrode layer. The first and second gate spacers and the first insulating layer have first, second and third hydrophobic surfaces, respectively. These hydrophobic surfaces are in direct contact with first, second and third sidewall surfaces of the gate electrode layer, respectively.

A method for forming a semiconductor device and a semiconductor device formed by the method are disclosed. In an embodiment, the method includes depositing a dummy dielectric layer on a fin extending from a substrate; depositing a dummy gate seed layer on the dummy dielectric layer; reflowing the dummy gate seed layer; etching the dummy gate seed layer; and selectively depositing a dummy gate material over the dummy gate seed layer, the dummy gate material and the dummy gate seed layer constituting a dummy gate.

A method is provided for forming a semiconductor device. A fin feature is formed on a semiconductor substrate, and a dummy gate feature is formed over the fin feature. The fin feature includes a sacrificial portion disposed over the semiconductor substrate, and a fin portion disposed over the sacrificial portion. The dummy gate feature is connected to the fin feature and the semiconductor substrate. Then, the sacrificial portion is removed to form a gap between the semiconductor substrate and the fin portion. A dielectric isolation layer is formed to fill the gap for electrically isolating the fin portion from the semiconductor substrate. Subsequently, source/drain features are formed over the dielectric isolation layer, and the dummy gate feature is processed to form a gate electrode feature on the fin portion.

A method of manufacturing a semiconductor device includes: forming a silicon oxide film covering each of a first main surface and a second main surface of a semiconductor substrate; forming a redistribution wiring on the first main surface side of the semiconductor substrate; and grinding the second main surface of the semiconductor substrate. This grinding step is performed in a state in which a thickness of the silicon oxide film positioned on the second main surface is equal to or larger than 10 nm and equal to or smaller than 30 nm.

A flash memory is provided and includes a substrate including a memory cell region; a memory transistor array including memory transistors and selecting transistors in the memory cell region; a functional layer covering outer surfaces of the memory transistors and selecting transistors, as well as surfaces of the substrate between adjacent memory transistors and selecting transistors; a dielectric layer covering top surfaces of the memory transistors and selecting transistors and fills gaps between each selecting transistor and a corresponding adjacent memory transistor; and air gaps formed between adjacent memory transistors. Each selecting transistor is used for selecting one column of memory transistors in the memory transistor array. The functional layer has a roughened surface capable of absorbing water. The air gaps in the flash memory are water vapor induced air gaps.

A semiconductor device includes a substrate, a first conductive feature disposed in a top portion of the substrate, a metal containing layer disposed on the first conductive feature, and a second conductive feature disposed on and through the metal containing layer and in physical contact with the first conductive feature. The metal containing layer includes an M-O—X group, M representing a metal atom, O representing an oxygen atom, and X representing an element other than hydrogen.

Various embodiments of the present application are directed towards a semiconductor-on-insulator (SOI) substrate. The SOI substrate includes a handle substrate; a device layer overlying the handle substrate; and an insulator layer separating the handle substrate from the device layer. The insulator layer meets the device layer at a first interface and meets the handle substrate at a second interface. The insulator layer comprises a getter material having a getter concentration profile. The handle substrate contains getter material and has a handle getter concentration profile. The handle getter concentration profile has a peak at the second interface and a gradual decline beneath the second interface until reaching a handle getter concentration.