Methods for repairing a defect of a lithographic mask with a particle beam are described. One such method can comprise the following steps: Processing the defect with the particle beam with a first set of processing parameters; processing the defect with the particle beam with a second set of processing parameters; wherein at least one parameter from the first set of processing parameters differs from the second set of processing parameters.

The present invention relates to a method for superimposing at least two images of a photolithographic mask, wherein the method comprises the following steps: (a) determining at least one first difference of at least one first image relative to design data of the photolithographic mask; (b) determining at least one second difference of at least one second image relative to design data of the photolithographic mask, or relative to the at least one first image; and (c) superimposing the at least one first image and the at least one second image taking account of the at least one first difference and the at least one second difference.

The present invention relates to a method for superimposing at least two images of a photolithographic mask, wherein the method comprises the following steps: (a) determining at least one first difference of at least one first image relative to design data of the photolithographic mask; (b) determining at least one second difference of at least one second image relative to design data of the photolithographic mask, or relative to the at least one first image; and (c) superimposing the at least one first image and the at least one second image taking account of the at least one first difference and the at least one second difference.

The inventive concept provides a substrate treating apparatus. The substrate treating apparatus includes a housing; a support unit positioned within the housing and configured to support a substrate; a liquid supply unit configured to supply a treating liquid to the substrate supported on the support unit; and a laser module configured to irradiate a laser to the substrate to which the treating liquid is supplied; and a vision module for monitoring a point at which the laser is irradiated among the substrate.

The inventive concept provides a substrate treating apparatus. The substrate treating apparatus includes a housing; a support unit positioned within the housing and configured to support a substrate; a liquid supply unit configured to supply a treating liquid to the substrate supported on the support unit; and a laser module configured to irradiate a laser to the substrate to which the treating liquid is supplied; and a vision module for monitoring a point at which the laser is irradiated among the substrate.

A method for forming a photomask includes receiving a mask substrate including a protecting layer and a shielding layer formed thereon, removing portions of the shielding layer to form a patterned shielding layer, and providing a BSE detector to monitor the removing of the portions of the shielding layer. When a difference in BSE intensities obtained from the BSE detector is greater than approximately 30%, the removing of the portions of the shielding layer is stopped. The BSE intensity in following etching loops becomes stable.

A method for forming a photomask includes receiving a mask substrate including a protecting layer and a shielding layer formed thereon, removing portions of the shielding layer to form a patterned shielding layer, and providing a BSE detector to monitor the removing of the portions of the shielding layer. When a difference in BSE intensities obtained from the BSE detector is greater than approximately 30%, the removing of the portions of the shielding layer is stopped. The BSE intensity in following etching loops becomes stable.

A method includes inspecting a mask to locate a defect region for a defect of the mask. A phase distribution of an aerial image of the defect region is acquired. A point spread function of an imaging system is determined. One or more repair regions of the mask are identified based on the phase distribution of the aerial image of the defect region and the point spread function. A repair process is performed to the one or more repair regions of the mask to form one or more repair features.

A method includes inspecting a mask to locate a defect region for a defect of the mask. A phase distribution of an aerial image of the defect region is acquired. A point spread function of an imaging system is determined. One or more repair regions of the mask are identified based on the phase distribution of the aerial image of the defect region and the point spread function. A repair process is performed to the one or more repair regions of the mask to form one or more repair features.

Method for the particle beam-induced etching of a lithography mask, more particularly a non-transmissive EUV lithography mask, having the steps of: a) providing the lithography mask in a process atmosphere, b) beaming a focused particle beam onto a target position on the lithography mask, c) supplying at least one first gaseous component to the target position in the process atmosphere, where the first gaseous component can be converted by activation into a reactive form, where the reactive form reacts with a material of the lithography mask to form a volatile compound, and d) supplying at least one second gaseous component to the target position in the process atmosphere, where the second gaseous component under predetermined process conditions with exposure to the particle beam forms a deposit comprising a compound of silicon with oxygen, nitrogen and/or carbon.