A mask, a manufacturing method thereof, and a patterning method employing the mask. In the mask, a plurality of masks can be combined into one mask. The pattern area (01) of the mask is provided with a first pattern section (10) and a second pattern section (20) which are not overlapped with each other; light of a first wavelength can run through the first pattern section (10) but light of a second wavelength cannot run through the first pattern section; the light of the second wavelength can run thorough the second pattern section (20) but the light of the first wavelength cannot run through the second pattern section; and the light of the first wavelength and the light of the second wavelength can run through the non-pattern area, or any of the light of the first wavelength and the light of the second wavelength cannot run through the non-pattern area. The mask is obtained by combining a plurality of masks.

A photomask and a method of forming the same, the photomask including a transparent substrate; a light shielding pattern on the transparent substrate, the light shielding pattern including molybdenum and silicon; and an etch stop layer covering at least a sidewall of the light shielding pattern, wherein the etch stop layer has an etch rate lower than an etch rate of the light shielding pattern with respect to an ammonia-based cleaning solution.

A photomask and a method of forming the same, the photomask including a transparent substrate; a light shielding pattern on the transparent substrate, the light shielding pattern including molybdenum and silicon; and an etch stop layer covering at least a sidewall of the light shielding pattern, wherein the etch stop layer has an etch rate lower than an etch rate of the light shielding pattern with respect to an ammonia-based cleaning solution.

This conductive composition includes: a conductive polymer (a) having a sulfonic acid group and/or a carboxy group; a basic compound (b) having at least one nitrogen-containing heterocyclic ring and an amino group; an aqueous polymer (c) having a hydroxyl group (excluding the conductive polymer (a)); a hydrophilic organic solvent (d); and water (e).

This conductive composition includes: a conductive polymer (a) having a sulfonic acid group and/or a carboxy group; a basic compound (b) having at least one nitrogen-containing heterocyclic ring and an amino group; an aqueous polymer (c) having a hydroxyl group (excluding the conductive polymer (a)); a hydrophilic organic solvent (d); and water (e).

The present invention aims to provide a reflective mask blank and a reflective mask which have a highly smooth multilayer reflective film as well as a low number of defects, and methods of manufacturing the same, and aims to prevent charge-up during a mask defect inspection using electron beams.

The present invention provides a reflective mask blank for EUV lithography in which a conductive underlying film, a multilayer reflective film that reflects exposure light, and an absorber film that absorbs exposure light are layered on a substrate, wherein the conductive underlying film is a single-layer film made of a tantalum-based material or a ruthenium-based material with a film thickness of greater than or equal to 1 nm and less than or equal to 10 nm that is formed adjacent to the multilayer reflective film, or the conductive underlying film is a multilayer film including a layer of a tantalum-based material with a film thickness of greater than or equal to 1 nm and less than or equal to 10 nm that is formed adjacent to the multilayer reflective film and a layer of a conductive material that is formed between the layer of the tantalum-based material and the substrate. The present invention also provides a reflective mask manufactured using the reflective mask blank. Furthermore, a semiconductor device is manufactured using the reflective mask.

The present invention aims to provide a reflective mask blank and a reflective mask which have a highly smooth multilayer reflective film as well as a low number of defects, and methods of manufacturing the same, and aims to prevent charge-up during a mask defect inspection using electron beams.

The present invention provides a reflective mask blank for EUV lithography in which a conductive underlying film, a multilayer reflective film that reflects exposure light, and an absorber film that absorbs exposure light are layered on a substrate, wherein the conductive underlying film is a single-layer film made of a tantalum-based material or a ruthenium-based material with a film thickness of greater than or equal to 1 nm and less than or equal to 10 nm that is formed adjacent to the multilayer reflective film, or the conductive underlying film is a multilayer film including a layer of a tantalum-based material with a film thickness of greater than or equal to 1 nm and less than or equal to 10 nm that is formed adjacent to the multilayer reflective film and a layer of a conductive material that is formed between the layer of the tantalum-based material and the substrate. The present invention also provides a reflective mask manufactured using the reflective mask blank. Furthermore, a semiconductor device is manufactured using the reflective mask.

Vacuum-integrated photoresist-less methods and apparatuses for forming metal hardmasks can provide sub-30 nm patterning resolution. A metal-containing (e.g., metal salt or organometallic compound) film that is sensitive to a patterning agent is deposited on a semiconductor substrate. The metal-containing film is then patterned directly (i.e., without the use of a photoresist) by exposure to the patterning agent in a vacuum ambient to form the metal mask. For example, the metal-containing film is photosensitive and the patterning is conducted using sub-30 nm wavelength optical lithography, such as EUV lithography.

Vacuum-integrated photoresist-less methods and apparatuses for forming metal hardmasks can provide sub-30 nm patterning resolution. A metal-containing (e.g., metal salt or organometallic compound) film that is sensitive to a patterning agent is deposited on a semiconductor substrate. The metal-containing film is then patterned directly (i.e., without the use of a photoresist) by exposure to the patterning agent in a vacuum ambient to form the metal mask. For example, the metal-containing film is photosensitive and the patterning is conducted using sub-30 nm wavelength optical lithography, such as EUV lithography.

A method of manufacturing a semiconductor device includes heating a pellicle disposed over a photomask. Actinic radiation is passed through the pellicle to selectively expose a photoresist layer on a substrate. The selectively exposed photoresist layer is developed to form a pattern in the photoresist layer.