A method for reducing resist consumption (RRC) is provided. The method includes treating a surface of a substrate using a RRC composition and forming a photoresist layer comprising a metal-containing material on the RRC composition treated surface. The RRC composition includes a solvent and an acid or a base. The solvent has a dispersion parameter between 10 and 25. The acid has an acid dissociation constant between -20 and 6.8. The base having an acid dissociation constant between 7.2 and 45.

In a method of manufacturing a semiconductor device, underlying structures comprising gate electrodes and source/drain epitaxial layers are formed, one or more layers are formed over the underlying structures, a hard mask layer is formed over the one or more layers, a groove pattern is formed in the hard mask layer, one or more first resist layers are formed over the hard mask layer having the groove pattern, a first photo resist pattern is formed over the one or more first resist layers, the one or more first resist layers are patterned by using the first photo resist pattern as an etching mask, thereby forming a first hard mask pattern, and the hard mask layer with the groove pattern are patterned by using the first hard mask pattern, thereby forming a second hard mask pattern.

Extreme ultraviolet (EUV) mask blanks, production systems therefor, and methods of reducing roughness are disclosed. The EUV mask blanks comprise a multilayer reflective stack on a substrate comprising a plurality of pairs of alternating layers comprising a first layer and a second layer, the first layer including a first element selected from the group consisting of Si, B, Al, Mg, Zr, Ba, Nb, Ti, Gd, Y, and Ca; and the second layer including a second element selected from the group consisting of Ru, Mo, Ta, Sb, Tc, Nb, Ir, Pt, and Pd. Some EUV mask blanks described herein include interface layer between the first layer and the second layer, the interface layer including an interface element selected from the group consisting of Si, B, C, Al, Mo, and Ru.

A self-assembled nanostructure comprises first domains and second domains. The first domains comprise a first block of a block copolymer material and an activatable catalyst. The second domains comprise a second block and substantially without the activatable catalyst. The activatable catalyst is capable of generating catalyst upon application of activation energy, and the generated catalyst is capable of reacting with a metal oxide precursor to provide a metal oxide. A semiconductor structure comprises such self-assembled nanostructure on a substrate.

A first layer is located over a substrate. The first layer includes a first dielectric component and a first conductive component. A first etching stop layer is located over the first dielectric component. A metal capping layer is located over the first conductive component. A second etching stop layer is located over the first etching stop layer and over the metal capping layer. A second layer is located over the second etching stop layer. The second layer includes a second dielectric component and a second conductive component. A third conductive component electrically interconnects the second conductive component to the first conductive component.

Method for producing coating composition applied to patterned resist film in lithography process for solvent development to reverse pattern. The method including: step obtaining hydrolysis condensation product by hydrolyzing and condensing hydrolyzable silane in non-alcoholic hydrophilic solvent; step of solvent replacement wherein non-alcoholic hydrophilic solvent replaced with hydrophobic solvent for hydrolysis condensation product. Method for producing semiconductor device, including: step of applying resist composition to substrate and forming resist film; step of exposing and developing formed resist film; step applying composition obtained by above production method to patterned resist film obtained during or after development in step, forming coating film between patterns; step of removing patterned resist film by etching and reversing patterns. Production method that exposure is performed using ArF laser (with wavelength of 193 nm) or EUV (with wavelength of 13.5 nm). Production method that development is negative development with organic solvent.

A method includes forming a first and a second contact opening to reveal a first and a second source/drain region, respectively, forming a mask layer having a first and a second portion in the first and the second contact openings, respectively, forming a first and a second sacrificial ILD in the first and the second contact openings, respectively, removing the first sacrificial ILD from the first contact opening, filling a filler in the first contact opening, and etching the second sacrificial ILD. The filler protects the first portion of the mask layer from being etched. An ILD is formed in the second contact opening and on the second portion of the mask layer. The filler and the first portion of the mask layer are removed using a wet etch to reveal the first contact opening. A contact plug is formed in the first contact opening.

A method may include forming in a substrate a first array of a first material of first linear structures, interspersed with a second array of a second material, of second linear structures, the first and second linear structures elongated along a first axis. The method may include generating a chop pattern in the first layer, comprising a third linear array, interspersed with a fourth linear array. The third and fourth linear arrays may be elongated along a second axis, forming a non-zero angle of incidence with respect to the first axis. The third linear array may include alternating portions of the first and second material, while the fourth linear array comprises an array of cavities, arranged within the patterning layer. The method may include elongating a first set of cavities along the first axis, to form a first set of elongated cavities bounded by the first material.

A method of forming an integrated circuit structure includes forming a first source/drain contact plug over and electrically coupling to a source/drain region of a transistor, forming a first dielectric hard mask overlapping a gate stack, recessing the first source/drain contact plug to form a first recess, forming a second dielectric hard mask in the first recess, recessing an inter-layer dielectric layer to form a second recess, and forming a third dielectric hard mask in the second recess. The third dielectric hard mask contacts both the first dielectric hard mask and the second dielectric hard mask.

A photolithographic exposure method for a memory. In a photolithographic process for making a memory, when exposure is performed by using a mask, regions with different exposure dimension requirements on the memory are divided into different exposure groups. Regions with the same exposure resolution requirement are divided into the same group. Different exposure modes of exposure that are capable of correspondingly satisfying resolution requirements of each group are performed to different groups during exposure. During exposure, different illumination modes are adopted to perform exposure. Firstly, a first exposure mode is adopted to perform exposure to a memory array cell exposure group, then a wafer is kept stationary on a supporting platform, and then a second exposure mode is adopted to perform exposure to the other structure exposure group; after the exposure of all groups is completed, one-step development is performed to complete pattern transfer.