In accordance with disclosed embodiments, there are provided systems, methods, and apparatuses for implementing bi-layer semiconducting oxides in a source/drain for low access and contact resistance of thin film transistors. For instance, there is disclosed in accordance with one embodiment a semiconductor device having therein a substrate; a bi-layer oxides layer formed from a first oxide material and a second oxide material, the first oxide material comprising a semiconducting oxide material and having different material properties from the second oxide material comprising a high mobility oxide material; a channel layer formed atop the substrate, the channel layer formed from the semiconducting oxide material of the bi-layer oxides layer; a high mobility oxide layer formed atop the channel layer, the high conductivity oxide layer formed from the high mobility oxide material of the bi-layer oxides layer; metallic contacts formed atop the high mobility oxide layer; a gate and a gate oxide material formed atop the high mobility oxide layer, the gate oxide material being in direct contact with the high mobility oxide layer; and spacers separating the metallic contacts from the gate and gate oxide material. Other related embodiments are disclosed.

A method of controlling an effective gate length in a vertical field effect transistor is provided. The method includes forming a vertical fin on a substrate, and forming a bottom spacer layer on the substrate adjacent to the vertical fin. The method further includes forming a dummy gate block adjacent to the vertical fin on the bottom spacer layer. The method further includes forming a top spacer adjacent to the vertical fin on the dummy gate block, and removing the dummy gate block to expose a portion of the vertical fin between the top spacer and bottom spacer layer. The method further includes forming an absorption layer on the exposed portion of the vertical fin. The method further includes heat treating the absorption layer and vertical fin to form a dopant modified absorption layer, and removing the dopant modified absorption layer.

A method of controlling an effective gate length in a vertical field effect transistor is provided. The method includes forming a vertical fin on a substrate, and forming a bottom spacer layer on the substrate adjacent to the vertical fin. The method further includes forming a dummy gate block adjacent to the vertical fin on the bottom spacer layer. The method further includes forming a top spacer adjacent to the vertical fin on the dummy gate block, and removing the dummy gate block to expose a portion of the vertical fin between the top spacer and bottom spacer layer. The method further includes forming an absorption layer on the exposed portion of the vertical fin. The method further includes heat treating the absorption layer and vertical fin to form a dopant modified absorption layer, and removing the dopant modified absorption layer.

A semiconductor device which includes a metal oxide film including a crystal part is provided. A semiconductor device which has a metal oxide film and high field-effect mobility is provided. A highly reliable semiconductor device including a metal oxide film is provided. The semiconductor device includes a first insulator, a first conductor formed over the first insulator, a second insulator formed over the first conductor, an oxide formed over the second insulator, a third insulator formed over the oxide, a second conductor formed over the third insulator, a fourth insulator formed over the third insulator and the second conductor, and a fifth insulator formed over the fourth insulator. The oxide contains In, M (M is Al, Ga, Y, or Sn), and Zn. The oxide includes a first crystal part and a second crystal part. The first crystal part has c-axis alignment. The second crystal part does not have c-axis alignment.

A semiconductor device which includes a metal oxide film including a crystal part is provided. A semiconductor device which has a metal oxide film and high field-effect mobility is provided. A highly reliable semiconductor device including a metal oxide film is provided. The semiconductor device includes a first insulator, a first conductor formed over the first insulator, a second insulator formed over the first conductor, an oxide formed over the second insulator, a third insulator formed over the oxide, a second conductor formed over the third insulator, a fourth insulator formed over the third insulator and the second conductor, and a fifth insulator formed over the fourth insulator. The oxide contains In, M (M is Al, Ga, Y, or Sn), and Zn. The oxide includes a first crystal part and a second crystal part. The first crystal part has c-axis alignment. The second crystal part does not have c-axis alignment.

Transistor structures may include a metal oxide contact buffer between a portion of a channel material and source or drain contact metallization. The contact buffer may improve control of transistor channel length by limiting reaction between contact metallization and the channel material. The channel material may be of a first composition and the contact buffer may be of a second composition.

Transistor structures may include a metal oxide contact buffer between a portion of a channel material and source or drain contact metallization. The contact buffer may improve control of transistor channel length by limiting reaction between contact metallization and the channel material. The channel material may be of a first composition and the contact buffer may be of a second composition.

A method of controlling an effective gate length in a vertical field effect transistor is provided. The method includes forming a vertical fin on a substrate, and forming a bottom spacer layer on the substrate adjacent to the vertical fin. The method further includes forming a dummy gate block adjacent to the vertical fin on the bottom spacer layer. The method further includes forming a top spacer adjacent to the vertical fin on the dummy gate block, and removing the dummy gate block to expose a portion of the vertical fin between the top spacer and bottom spacer layer. The method further includes forming an absorption layer on the exposed portion of the vertical fin. The method further includes heat treating the absorption layer and vertical fin to form a dopant modified absorption layer, and removing the dopant modified absorption layer.

A method of controlling an effective gate length in a vertical field effect transistor is provided. The method includes forming a vertical fin on a substrate, and forming a bottom spacer layer on the substrate adjacent to the vertical fin. The method further includes forming a dummy gate block adjacent to the vertical fin on the bottom spacer layer. The method further includes forming a top spacer adjacent to the vertical fin on the dummy gate block, and removing the dummy gate block to expose a portion of the vertical fin between the top spacer and bottom spacer layer. The method further includes forming an absorption layer on the exposed portion of the vertical fin. The method further includes heat treating the absorption layer and vertical fin to form a dopant modified absorption layer, and removing the dopant modified absorption layer.

A disclosed transistor structure includes a gate electrode, an active layer, a source electrode, a drain electrode, an insulating layer separating the gate electrode from the active layer, and a carrier modification device that reduces short channel effects by reducing carrier concentration variations in the active layer. The carrier modification device may include a capping layer in contact with the active layer that acts to increase a carrier concentration in the active layer. Alternatively, the carrier modification device may include a first injection layer in contact with the source electrode and the active layer separating the source electrode from the active layer, and a second injection layer in contact with the drain electrode and the active layer separating the drain electrode from the active layer. The first and second injection layers may act to reduce a carrier concentration within the active layer near the source electrode and the drain electrode.