Provided is a hydrogenation annealing method using a microwave, which performs hydrogenation annealing at a low temperature and with low power in a manufacturing process of a thin film transistor (TFT) for a display device. The hydrogenation annealing method is constituted by a loading step of loading a device requiring hydrogenation annealing into a chamber and an annealing step of irradiating a microwave having a frequency in an industrial scientific medical (ISM) band into the chamber into which the device is loaded. As hydrogenation annealing is performed at a low temperature by using the microwave for an oxide semiconductor TFT or LTPS having very large electron mobility, high integrated energy is transmitted to the device by the microwave, thereby implementing recoupling of hydrogen atoms which have been performed only at a high temperature, even at a low temperature.

A method of manufacturing semiconductor devices in a semiconductor wafer comprises forming charge compensation device structures in the semiconductor wafer. An electric characteristic related to the charge compensation device structures is measured. At least one of proton irradiation and annealing parameters are adjusted based on the measured electric characteristic. The semiconductor wafer is irradiated with protons and annealed based on the at least one of the adjusted proton irradiation and annealing parameters. Laser beam irradiation parameters are adjusted with respect to different positions on the semiconductor wafer based on the measured electric characteristic. The semiconductor wafer is irradiated with a photon beam at the different positions on the wafer based on the photon beam irradiation parameters.

Surface treatment processes for treating a workpiece with organic radicals are provided. In one example implementation, a method for processing a workpiece having a semiconductor material and a carbon containing layer (e.g., photoresist) can include a surface treatment process on the workpiece. The surface treatment process can include generating one or more species in a first chamber (e.g., a plasma chamber). The surface treatment process can include mixing one or more hydrocarbon radicals with the species to create a mixture. The surface treatment process can include exposing the carbon containing layer to the mixture in a second chamber (e.g., a processing chamber).

The present application discloses a semiconductor device and a method for forming a p-type conductive channel in a diamond using an abrupt heterojunction, which pertain to the technical field of fabrication of semiconductor devices. The method includes: forming a diamond layer on a substrate; forming one or multiple layers of a heterogeneous elementary substance or compound having an acceptor characteristic on an upper surface of the diamond layer; forming a heterojunction at an interface between the diamond layer and an acceptor layer; forming two-dimensional hole gas at one side of the diamond layer with a distance of 10 nm-20 nm away from the heterojunction; and using the two-dimensional hole gas as a p-type conductive channel. The method enables a concentration and a mobility of carriers to maintain stable at a temperature range of 0 C.-1000 C., thereby realizing normal operation of the diamond device at high temperature environment.

The present application discloses a method for fabricating a thin film transistor including the steps of: sequentially forming an active layer, a gate insulating layer, a gate, and a capacitive insulating layer on a substrate, the gate insulating layer isolating the active layer from the gate; a hydrogen-blocking layer is formed on the side of the capacitive insulating layer facing away from the substrate, and the hydrogen-blocking layer covering the capacitive insulating layer; and performing hydrogenation treatment to the gate insulating layer and the active layer. The present application also discloses a thin film transistor and a display apparatus. In improving the flexibility of the AMOLED display apparatus while ensuring the hydrogenation effect of the polysilicon thin film transistor, the fabricated thin film transistor has high electron mobility, and the display apparatus has a good display performance.

Surface treatment processes for treating low-k dielectric materials are provided. One example implementation can include a method for processing a workpiece. The workpiece can include a silicon and carbon containing film material. The method can include treating the workpiece with a surface treatment process. The surface treatment process can include generating one or more species in a first chamber; mixing one or more hydrocarbon molecules with the species to create a mixture comprising one or more organic radicals; and exposing the silicon and carbon containing layer on the workpiece to the mixture in a second chamber.

Processes for surface treatment of a workpiece are provided. In one example implementation, a method can include performing an organic radical based surface treatment process on a workpiece. The organic radical based surface treatment process can include generating one or more species in a first chamber. The surface treatment process can include mixing one or more hydrocarbon molecules with the species to create a mixture. The mixture can include one or more organic radicals. The surface treatment process can include exposing a semiconductor material on the workpiece to the mixture in a second chamber.

Surface treatment processes for treating a workpiece with organic radicals are provided. In one example implementation, a method for processing a workpiece having a semiconductor material and a carbon containing layer (e.g., photoresist) can include a surface treatment process on the workpiece. The surface treatment process can include generating one or more species in a first chamber (e.g., a plasma chamber). The surface treatment process can include mixing one or more hydrocarbon radicals with the species to create a mixture. The surface treatment process can include exposing the carbon containing layer to the mixture in a second chamber (e.g., a processing chamber).

an array substrate, a method of manufacturing the array substrate, and a display device are provided. The array substrate includes: a base substrate; a first thin film transistor and a second thin film transistor on the base substrate, wherein the first thin film transistor comprises a first active layer, the second thin film transistor comprises a second active layer, and the second active layer is on a side of the first active layer away from the base substrate; and an interlayer dielectric layer and a first buffer layer between the first active layer and the second active layer, wherein the interlayer dielectric layer is capable of supplying hydrogen and the first buffer layer is capable of blocking hydrogen.

A method of manufacturing a semiconductor device includes accommodating a substrate in a process chamber; supplying a first gas containing oxygen into the process chamber; generating plasma in the process chamber by exciting the first gas; supplying a second gas containing hydrogen into the process chamber and adjusting a hydrogen concentration distribution in the process chamber according to a density distribution of the plasma in the process chamber; and processing the substrate with oxidizing species generated by the plasma.