A thin film transistor and its manufacturing method, an array substrate and its manufacturing method, and a display device are provided. The thin film transistor includes a gate electrode, a source electrode, a drain electrode, an active layer and a gate insulation layer. The gate insulation layer is provided above the active layer, the gate, the source electrode and the drain electrode are provided on a same layer above the gate insulation layer, the active layer and the source electrode are connected through a first connection electrode, and the active layer and the drain electrode are connected through a second connection electrode. The thin film transistor can be formed by three times of patterning processes, by which the process time period is shortened, the process yield is improved, and the process cost is reduced, and so on.

According to embodiments, a semiconductor device is provided. The semiconductor device includes an insulation layer, an electrode, and a groove. The insulation layer is provided on a surface of a substrate. The electrode is buried in the insulation layer, and a first end surface of the electrode is exposed from the insulation layer. The groove is formed around the electrode on the surface of the substrate. The groove has an outside surface of the electrode as one side surface, and the groove is opened on the surface side of the insulation layer. The first end surface of the electrode buried in the insulation layer protrudes from the surface of the insulation layer.

A method for fabricating a shield gate trench MOSFET, including the following steps: forming a hard mask layer and defining a gate forming region; forming a top trench by means of both anisotropic and isotropic etching; forming an oxidative barrier layer; etching back the oxidative barrier layer, and then forming a bottom trench by means of anisotropic etching; forming a bottom oxidative layer by means of thermal oxidative self-alignment; removing the oxidative barrier layer; forming a gate dielectric film; forming a first polysilicon layer; etching back the first polysilicon layer to form respectively therefrom a polysilicon gate and a bottom shield polysilicon; forming a inter-poly dielectric isolation layer; etching back the inter-poly dielectric isolation layer; forming a second polysilicon layer and forming a shield polysilicon by means of superposition with the bottom shield polysilicon.

A method for fabricating a shield gate trench MOSFET, including the following steps: forming a hard mask layer and defining a gate forming region; forming a top trench by means of both anisotropic and isotropic etching; forming an oxidative barrier layer; etching back the oxidative barrier layer, and then forming a bottom trench by means of anisotropic etching; forming a bottom oxidative layer by means of thermal oxidative self-alignment; removing the oxidative barrier layer; forming a gate dielectric film; forming a first polysilicon layer; etching back the first polysilicon layer to form respectively therefrom a polysilicon gate and a bottom shield polysilicon; forming a inter-poly dielectric isolation layer; etching back the inter-poly dielectric isolation layer; forming a second polysilicon layer and forming a shield polysilicon by means of superposition with the bottom shield polysilicon.

A method includes performing a first etching process on a backside of a substrate to expose a dummy contact structure, performing a first deposition process to deposit a first dielectric layer around the dummy contract structure, performing a second deposition process to deposit an oxide layer on the first dielectric layer, removing the dummy contract structure to form a trench, depositing a sacrificial layer on sidewalls of the trench, depositing a second dielectric layer on the sacrificial layer, filling the trench with a conductive material, and removing the sacrificial layer to form an air spacer between the first dielectric layer and the second dielectric layer.

A method includes performing a first etching process on a backside of a substrate to expose a dummy contact structure, performing a first deposition process to deposit a first dielectric layer around the dummy contract structure, performing a second deposition process to deposit an oxide layer on the first dielectric layer, removing the dummy contract structure to form a trench, depositing a sacrificial layer on sidewalls of the trench, depositing a second dielectric layer on the sacrificial layer, filling the trench with a conductive material, and removing the sacrificial layer to form an air spacer between the first dielectric layer and the second dielectric layer.

Methods of processing thin film by oxidation at high pressure are described. The methods are generally performed at pressures greater than 2 bar. The methods can be performed at lower temperatures and have shorter exposure times than similar methods performed at lower pressures. Some methods relate to oxidizing tungsten films to form self-aligned pillars.

Methods of processing thin film by oxidation at high pressure are described. The methods are generally performed at pressures greater than 2 bar. The methods can be performed at lower temperatures and have shorter exposure times than similar methods performed at lower pressures. Some methods relate to oxidizing tungsten films to form self-aligned pillars.

A semiconductor process system etches gate metals on semiconductor wafers. The semiconductor process system includes a machine learning based analysis model. The analysis model dynamically selects process conditions for an etching process. The process system then uses the selected process conditions data for the next etching process.

A semiconductor process system etches gate metals on semiconductor wafers. The semiconductor process system includes a machine learning based analysis model. The analysis model dynamically selects process conditions for an etching process. The process system then uses the selected process conditions data for the next etching process.