Methods of inspecting photomasks are provided. A method of inspecting a photomask includes electronically inspecting a first mask pattern in a mask region of the photomask and refraining from electronically inspecting a separate second mask pattern in the mask region of the photomask. The first mask pattern includes a geometric feature that corresponds to at least a portion of the second mask pattern. Moreover, the mask region is outside of a scribe lane region of the photomask. Related methods of manufacturing photomasks and methods of manufacturing semiconductor devices are also provided.

Disclosed is a phase-shift blankmask, in which a light-shielding film includes a metal compound and having a structure of a multi-layer film or a continuous film, which includes a first light-shielding layer and a second light-shielding layer. The second light-shielding layer has higher optical density at an exposure wavelength per unit thickness (Å) than the first light-shielding layer. The first light-shielding layer occupies 70% to 90% of the whole thickness of the light-shielding film. With this, the blankmask secures a light-shielding effect, has an improved etching speed, and makes a resist film thinner, thereby achieving a fine pattern.

Disclosed is a phase-shift blankmask, in which a light-shielding film includes a metal compound and having a structure of a multi-layer film or a continuous film, which includes a first light-shielding layer and a second light-shielding layer. The second light-shielding layer has higher optical density at an exposure wavelength per unit thickness (Å) than the first light-shielding layer. The first light-shielding layer occupies 70% to 90% of the whole thickness of the light-shielding film. With this, the blankmask secures a light-shielding effect, has an improved etching speed, and makes a resist film thinner, thereby achieving a fine pattern.

The present disclosure relates to lithographic masks and, more particularly, to a lithographic mask substrate structure and methods of manufacture. The mask includes a sub-resolution assist feature (SRAF) formed on a quartz substrate and composed of a patterned transition film and absorber layer.

A photomask includes a light transmission substrate, and a transfer pattern disposed over the light transmission substrate, a shape of the transfer pattern being transferred onto a wafer by an exposure process. The transfer pattern comprises a first transfer pattern having a closed loop shape and having a first thickness, and a plurality of second transfer patterns disposed in an opening surrounded by the first transfer pattern, the plurality of second transfer patterns being arrayed in a first direction such that adjacent second transfer patterns are spaced apart from each other by a first distance, the second transfer patterns having a second thickness which is less than the first thickness of the first transfer pattern.

A photomask includes a light transmission substrate, and a transfer pattern disposed over the light transmission substrate, a shape of the transfer pattern being transferred onto a wafer by an exposure process. The transfer pattern comprises a first transfer pattern having a closed loop shape and having a first thickness, and a plurality of second transfer patterns disposed in an opening surrounded by the first transfer pattern, the plurality of second transfer patterns being arrayed in a first direction such that adjacent second transfer patterns are spaced apart from each other by a first distance, the second transfer patterns having a second thickness which is less than the first thickness of the first transfer pattern.

Provided is a mask blank .

A transmittance adjusting film is provided on a phase shift film; the phase shift film generates a phase difference of 150 degrees or more and 210 degrees or less between an ArF excimer laser exposure light transmitted through the phase shift film and the exposure light transmitted through the air for a same distance as a thickness of the phase shift film; and a refractive index nu with respect to a wavelength of the exposure light, an extinction coefficient ku with respect to the wavelength of the exposure light, and a thickness du[nm] of the transmittance adjusting film satisfy both equations (1) and (2) given below.

[00001]${\text{d}}_{\text{U}}\le \text{-17}\text{.63}\times {\text{n}}_{\text{U}}{}^{\text{3}}\text{+142}\text{.0}\times {\text{n}}_{\text{U}}{}^2\text{-364}\text{.9}\times {\text{n}}_{\text{U}}\text{+315}\text{.8}$

[00002]${\text{d}}_{\text{U}}\ge \text{-2}\text{.805}\times {\text{k}}_{\text{U}}{}^3\text{+19}\text{.48}\times {\text{k}}_{\text{U}}{}^{\text{2}}\text{-43}\text{.58}\times {\text{k}}_{\text{U}}\text{+38}\text{.11}$

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.