The present application discloses a thin-film deposition method and a semiconductor device. The thin-film deposition method in the present application includes: providing a substrate; performing thin-film deposition on the substrate by using a thin-film deposition technology to form a first deposited layer; introducing a purge gas to perform impurity purge treatment on the first deposited layer to form a purified deposited layer; and forming a thin-film layer by the purified deposited layer. In the thin-film deposition method of the present application, the thin-film deposition technology is adopted to form the deposited layer, and impurity purge treatment is performed on the deposited layer.

The present application discloses a thin-film deposition method and a semiconductor device. The thin-film deposition method in the present application includes: providing a substrate; performing thin-film deposition on the substrate by using a thin-film deposition technology to form a first deposited layer; introducing a purge gas to perform impurity purge treatment on the first deposited layer to form a purified deposited layer; and forming a thin-film layer by the purified deposited layer. In the thin-film deposition method of the present application, the thin-film deposition technology is adopted to form the deposited layer, and impurity purge treatment is performed on the deposited layer.

A bonding system includes a surface modifying apparatus configured to modify a bonding surface of a first substrate and a bonding surface of a second substrate; a surface hydrophilizing apparatus configured to hydrophilize the modified bonding surface of the first substrate and the modified bonding surface of the second substrate; a bonding apparatus configured to perform bonding of the hydrophilized bonding surface of the first substrate and the hydrophilized bonding surface of the second substrate in a state that the bonding surfaces face each other; and a cleaning apparatus configured to clean, before the bonding is performed, a non-bonding surface of, between the first substrate and the second substrate, at least one which is maintained flat when the bonding is performed, the not-bonding surface being opposite to the bonding surface.

A bonding system includes a surface modifying apparatus configured to modify a bonding surface of a first substrate and a bonding surface of a second substrate; a surface hydrophilizing apparatus configured to hydrophilize the modified bonding surface of the first substrate and the modified bonding surface of the second substrate; a bonding apparatus configured to perform bonding of the hydrophilized bonding surface of the first substrate and the hydrophilized bonding surface of the second substrate in a state that the bonding surfaces face each other; and a cleaning apparatus configured to clean, before the bonding is performed, a non-bonding surface of, between the first substrate and the second substrate, at least one which is maintained flat when the bonding is performed, the not-bonding surface being opposite to the bonding surface.

One process that may be used to remove material from a surface is ion etching. In certain cases, ion etching involves delivery of both ions and a reactive gas to a substrate. The disclosed embodiments permit local high pressure delivery of reactive gas to a substrate while maintaining a much lower pressure on portions of the substrate that are outside of the local high pressure delivery area. The low pressure is achieved by confining the high pressure reactant delivery to a small area and vacuuming away excess reactants and byproducts as they leave this small area and before they enter the larger substrate processing region. The disclosed techniques may be used to increase throughput while minimizing deleterious collisions between ions and other species present in the substrate processing region.

One process that may be used to remove material from a surface is ion etching. In certain cases, ion etching involves delivery of both ions and a reactive gas to a substrate. The disclosed embodiments permit local high pressure delivery of reactive gas to a substrate while maintaining a much lower pressure on portions of the substrate that are outside of the local high pressure delivery area. The low pressure is achieved by confining the high pressure reactant delivery to a small area and vacuuming away excess reactants and byproducts as they leave this small area and before they enter the larger substrate processing region. The disclosed techniques may be used to increase throughput while minimizing deleterious collisions between ions and other species present in the substrate processing region.

Embodiments relate to a grid short clearing system is provided for gridded ion beam sources used in industrial applications for materials processing systems that reduces grid damage during operation. In various embodiments, the ion source is coupled to a process chamber and a grid short clearing system includes methods for supplying a gas to the process chamber and setting the gas pressure to a predetermined gas pressure in the range between 50 to 750 Torr, applying an electrical potential difference between each adjacent pair of grids using a current-limited power supply, and detecting whether or not the grid shorts are cleared. The electrical potential difference between the grids is at least 10% lower than the DC electrical breakdown voltage between the grids with no contaminants.

Embodiments relate to a grid short clearing system is provided for gridded ion beam sources used in industrial applications for materials processing systems that reduces grid damage during operation. In various embodiments, the ion source is coupled to a process chamber and a grid short clearing system includes methods for supplying a gas to the process chamber and setting the gas pressure to a predetermined gas pressure in the range between 50 to 750 Torr, applying an electrical potential difference between each adjacent pair of grids using a current-limited power supply, and detecting whether or not the grid shorts are cleared. The electrical potential difference between the grids is at least 10% lower than the DC electrical breakdown voltage between the grids with no contaminants.

A bonding system includes a surface modifying apparatus configured to modify a bonding surface of a first substrate and a bonding surface of a second substrate; a surface hydrophilizing apparatus configured to hydrophilize the modified bonding surface of the first substrate and the modified bonding surface of the second substrate; a bonding apparatus configured to perform bonding of the hydrophilized bonding surface of the first substrate and the hydrophilized bonding surface of the second substrate in a state that the bonding surfaces face each other; and a cleaning apparatus configured to clean, before the bonding is performed, a non-bonding surface of, between the first substrate and the second substrate, at least one which is maintained flat when the bonding is performed, the not-bonding surface being opposite to the bonding surface.

A bonding system includes a surface modifying apparatus configured to modify a bonding surface of a first substrate and a bonding surface of a second substrate; a surface hydrophilizing apparatus configured to hydrophilize the modified bonding surface of the first substrate and the modified bonding surface of the second substrate; a bonding apparatus configured to perform bonding of the hydrophilized bonding surface of the first substrate and the hydrophilized bonding surface of the second substrate in a state that the bonding surfaces face each other; and a cleaning apparatus configured to clean, before the bonding is performed, a non-bonding surface of, between the first substrate and the second substrate, at least one which is maintained flat when the bonding is performed, the not-bonding surface being opposite to the bonding surface.