Improved methods for chemically etching silicon are provided herein. In some embodiments, a method of etching a silicon material includes: (a) exposing the silicon material to a halogen-containing gas; (b) evacuating the halogen-containing gas from the semiconductor processing chamber; (c) exposing the silicon material to an amine vapor to etch a monolayer of the silicon material; (d) evacuating the amine vapor from the semiconductor processing chamber and; (e) optionally repeating (a)-(d) to etch the silicon material to a predetermined thickness.

A method of forming a high-? dielectric cap layer on a semiconductor structure formed on a substrate includes depositing the high-? dielectric cap layer on the semiconductor structure, depositing a sacrificial silicon cap layer on the high-? dielectric cap layer, performing a post cap anneal process to harden and densify the as-deposited high-? dielectric cap layer, and removing the sacrificial silicon cap layer.

Disclosed herein are systems and methods for treating the surface of a microelectronic substrate, and in particular, relate to an apparatus and method for scanning the microelectronic substrate through a cryogenic fluid mixture used to treat an exposed surface of the microelectronic substrate. The fluid mixture may be expanded through a nozzle to form an aerosol spray or gas cluster jet (GCJ) spray may impinge the microelectronic substrate and remove particles from the microelectronic substrate's surface. In one embodiment, the fluid mixture may be maintained to prevent liquid formation within the fluid mixture prior to passing the fluid mixture through the nozzle. The fluid mixture may include nitrogen, argon, helium, neon, xenon, krypton, carbon dioxide, or any combination thereof.

A method includes bonding a front side surface of a first wafer to a second wafer; performing a multi-trimming process on the first and second wafers from a back side surface of the first wafer, the multi-trimming process comprising: performing a first trimming step from the back side surface of the first wafer to cut through a periphery of the first wafer; performing a second trimming step on the second wafer to partially cut a periphery of the second wafer to form a first step-like structure; and performing a third trimming step on the second wafer to partially cut the periphery of the second wafer to form a second step-like structure connecting down from the first step-like structure; after performing the multi-trimming process, forming a coating material at least over the periphery of the second wafer.

A plasma treatment method includes: creating a plasma from a mixed gas containing carbon and nitrogen to generate CN active species, and treating a surface of a semiconductor substrate with the CN active species.

A substrate processing apparatus of an exemplary embodiment includes a liquid processing unit, a detection unit, and a post-processing unit. The liquid processing unit supplies a liquid to a substrate to form a liquid film on the substrate. The detection unit detects the amount of a liquid on the substrate to determine whether the amount of the liquid is acceptable or not. The post-processing unit processes the substrate having the liquid film formed thereon.

Disclosed herein are systems and methods for treating the surface of a microelectronic substrate, and in particular, relate to an apparatus and method for scanning the microelectronic substrate through a cryogenic fluid mixture used to treat an exposed surface of the microelectronic substrate. The fluid mixture may be expanded through a nozzle to form an aerosol spray or gas cluster jet (GCJ) spray may impinge the microelectronic substrate and remove particles from the microelectronic substrate's surface. In one embodiment, the fluid mixture may be maintained to prevent liquid formation within the fluid mixture prior to passing the fluid mixture through the nozzle. The fluid mixture may include nitrogen, argon, helium, neon, xenon, krypton, carbon dioxide, or any combination thereof.

The present invention provides a manufacture method of an AMOLED pixel driving circuit. The method utilizes the oxide semiconductor thin film transistor to be the switch thin film transistor of the AMOLED pixel driving circuit to reduce the leakage current of the switch thin film transistor, and the P type polysilicon thin film transistor manufactured by utilizing the Solid Phase Crystallization is employed to be the drive thin film transistor of the AMOLED pixel driving circuit to promote the mobility, the equality and the reliability of the drive thin film transistor, and utilizing the P type thin film transistor to be the drive thin film transistor can form the constant current type OLED element, which is more stable than the source follower type OLED formed by the N type thin film transistor, and meanwhile, the parasitic capacitance is decreased with the top gate structure.

Contamination of a bottom surface of a substrate caused by a processing liquid used for cleaning a top surface of the substrate can be suppressed. After performing a liquid processing on the top surface of the substrate and a liquid processing on the bottom surface of the substrate in parallel while rotating the substrate by a substrate holding/rotating unit, when stopping the liquid processing on the top surface of the substrate and the liquid processing on the bottom surface of the substrate, a control unit 18 stops a supply of the processing liquid onto the top surface of the substrate by a processing liquid supply device 73, and then, stops a supply of the processing liquid onto the bottom surface of the substrate by a processing liquid supply device 71.

The present invention provides a manufacture method of an AMOLED pixel driving circuit. The method utilizes the oxide semiconductor thin film transistor to be the switch thin film transistor of the AMOLED pixel driving circuit to reduce the leakage current of the switch thin film transistor, and the P type polysilicon thin film transistor manufactured by utilizing the Solid Phase Crystallization is employed to be the drive thin film transistor of the AMOLED pixel driving circuit to promote the mobility, the equality and the reliability of the drive thin film transistor, and utilizing the P type thin film transistor to be the drive thin film transistor can form the constant current type OLED element, which is more stable than the source follower type OLED formed by the N type thin film transistor, and meanwhile, the parasitic capacitance is decreased with the top gate structure.