Abstract: A photomask for measuring lens aberration, a method of manufacturing the photomask, and a method of measuring lens aberration using the photomask are provided. In an embodiment, the photomask includes a transparent substrate having first and second surfaces. A reference pattern group and an encoded pattern group are formed on the second surface of the transparent substrate, spaced apart from each other. An aperture that includes a Fresnel zone is formed to face the second surface on the second surface of the transparent substrate. Light throughput and measurement efficiency are improved.

Abstract: A semiconductor device and a method for controlling its patterns is described where the electrical characteristics of the patterns formed by a double patterning process may be individually controlled responsive to critical dimensions (CDs) of the patterns. The method includes controlling two or more patterns having different CDs to optimally operate the patterns. The patterns may be individually controlled by signals provided to the patterns on the basis of the pattern's CDs. The signals may be controlled by controlling the magnitudes or the application time of the signals provided to the respective patterns.

Abstract: A mask corrects for an optical proximity effect (OPE). A dummy pattern having a phase-edge effect is formed on a mask substrate. The phase-edge effect reduces the intensity of light at the boundary of two transmitting regions from through transmitted light has a phase difference. A pattern can then be formed in a photolithographic process using the phase-edge effect. A difference between “isolated” and “dense” patterns formed on a wafer can be reduced by forming a dummy pattern in an isolated pattern region of the mask and making the diffraction pattern of the isolated pattern the same as that of the dense pattern, thereby improving the total focus margin. Because the intensity of light is reduced at the boundary between a first region in which the phase of the transmitted light is 0° and a second region in which the phase of the transmitted light is 180°, for example, a photoresist layer is not photosensitized.

Abstract: A semiconductor device having a fin type active area includes a plurality of active regions, a first device isolation layer and a recessed second device isolation layer disposed in a direction of gate electrodes of the semiconductor device. A recessed second device isolation layer and a first device isolation layer are disposed in a vertical direction of the gate electrodes. The first device isolation layer and the plurality of active regions are alternately disposed in a first direction of the plurality of active regions.

Abstract: Provided are a compensating mask, a multi-optical system using the compensating mask, and a method of compensating for a 3-dimensional (3-D) mask effect using the compensating mask. Methods of compensating for a 3-D mask effect using a compensating mask may include generating a first kernel corresponding to a normal mask used for forming a minute pattern, generating a second kernel corresponding to a compensating mask, mixing the first kernel corresponding to the normal mask with the second kernel corresponding to the compensating mask, and generating a multi-optical system kernel corresponding to mixing the first kernel and the second kernel.

Abstract: A method of manufacturing a mask includes designing a second mask data pattern for forming a first mask data pattern, creating a first emulation pattern, which is determined from the second mask data pattern, using a first emulation, creating a second emulation pattern, which is determined from the first emulation pattern, using a second emulation, comparing a pattern, in which the first and second emulation patterns overlap, with the first mask data pattern, and manufacturing a mask layer, which corresponds to the second mask data pattern, according to results of the comparison.

Abstract: Provided are example embodiments of the invention including a range of polymer structures suitable for incorporation in barrier compositions for use, for example, in immersion photolithography in combination with a suitable solvent or solvent system. These polymers exhibit a weight average molecular weight (Mw) of 5,000 to 200,000 daltons and may be generally represented by formula I: wherein the expressions (1+m+n)=1; 0.1?(1/(1+m+n))?0.7; 0.3?(m/(1+m+n))?0.9; and 0.0?(n/(1+m+n))?0.6 are satisfied; R1, R2 and R3 are C1 to C5 alkyl, C1 to C5 alkoxy and hydroxyl groups; and Z represents an alkene that includes at least one hydrophilic group. Barrier coating compositions will include an organic solvent or solvent system selected from C3 to C10 alcohol-based organic solvents, C4 to C12 alkane-based organic solvents and mixtures thereof.

Abstract: A method of forming hard mask employs a double patterning technique. A first hard mask layer is formed on a substrate, and a first sacrificial pattern is formed on the first hard mask layer by photolithography. Features of the first sacrificial pattern are spaced from one another by a first pitch. A second hard mask layer is then formed conformally on the first sacrificial pattern and the first hard mask layer so as to delimit recesses between adjacent features of the first sacrificial pattern. Upper portions of the second hard mask layer are removed to expose the first sacrificial pattern, and the exposed first sacrificial pattern and the second sacrificial pattern are removed. The second hard mask layer and the first hard mask layer are then etched to form a hard mask composed of residual portions of the first hard mask layer and the second hard mask layer.

Abstract: A fine pattern is formed in an integrated circuit substrate, by forming a sacrificial pattern on the integrated circuit substrate. The sacrificial pattern includes tops and side walls. Atomic layer deposition is then performed to atomic layer deposit a mask material layer on the sacrificial pattern, including on the tops and the side walls thereof, and on the integrated circuit substrate therebetween. The mask material layer that was atomic layer deposited is then etched, to expose the top and the integrated circuit therebetween, such that a mask material pattern remains on the side walls. The sacrificial pattern is then removed, and the integrated circuit substrate is then etched through the mask material pattern that remains.

Abstract: Provided are a flash memory device and a method of manufacturing the same. The flash memory device includes strings. Each of the strings has a string selection line, a ground selection line, and an odd number of word lines formed between the string selection line and the ground selection line.

Abstract: A method for cleaning a substrate on which a silicon layer and a silicon germanium layer are formed and exposed, and method for fabricating a semiconductor device using the cleaning method are disclosed. The cleaning method comprises preparing a semiconductor substrate on which a silicon layer and a silicon germanium layer are formed and exposed; and performing a first cleaning sub-process that uses a first cleaning solution to remove a native oxide layer from the semiconductor substrate. The cleaning method further comprises performing a second cleaning sub-process on the semiconductor substrate after performing the first cleaning sub-process, wherein the second cleaning sub-process comprises using a second cleaning solution. In addition, the second cleaning solution comprises ammonium hydroxide (NH4OH), hydrogen peroxide (H2O2), and deionized water (H2O), and the second cleaning solution comprises at least 200 times more deionized water (H2O) than ammonium hydroxide (NH4OH) by volume.

Abstract: In the method of forming a mask structure, a first mask is formed on a substrate where the first mask includes a first mask pattern having a plurality of mask pattern portions having openings therebetween and a second mask pattern having a corner portion of which an inner side wall that is curved. A sacrificial layer is formed on the first mask. A hard mask layer is formed on the sacrificial layer. After the hard mask layer is partially removed until the sacrificial layer adjacent to the corner portion is exposed, a second mask is formed from the hard mask layer remaining in the space after removing the sacrificial layer. A minute pattern having a fine structure may be easily formed on the substrate.

Abstract: An oligomer probe array having improved reaction yield is provided. The oligomer probe array includes a substrate, an immobilization layer on the substrate, a plurality of nano particles coupled with a surface of the immobilization layer, and a plurality of oligomer probes coupled with surfaces of the nano particles.

Abstract: A method of manufacturing a mask includes designing a first mask data pattern, designing a second mask data pattern for forming the first mask data pattern, acquiring a first emulation pattern, which is predicted from the second mask data pattern, using layout-based Self-Aligning Double Patterning (SADP) emulation, comparing the first emulation pattern with the first mask data pattern, and modifying the second mask data pattern according to results of the comparison. The method further includes performing Optical Proximity Correction (OPC) on the modified second mask data pattern, acquiring second emulation patterns, which are predicted from the second mask data pattern on which the OPC has been performed, using image-based SADP emulation, and comparing the second emulation patterns and the first mask data pattern and manufacturing a first mask layer, which corresponds to the second mask data pattern on which the OPC has been performed, according to the results of the comparison.

Abstract: A semiconductor device includes a substrate, and a plurality of active pillars arranged in a pattern of alternating even and odd rows and alternating even and odd columns, each active pillar extending from the substrate and including a channel portion, wherein the odd columns include active pillars spaced at a first pitch, the first pitch being determined in the column direction, the even columns include active pillars spaced at the first pitch, the even rows include active pillars spaced at a third pitch, the third pitch being determined in the row direction the odd rows include active pillars spaced at the third pitch, and active pillars in the even columns are offset by a second pitch from active pillars in the odd columns, the second pitch being determined in the column direction.

Abstract: A method of forming a semiconductor device includes forming a first mask pattern on a target layer, the first mask pattern exposing a first portion of the target layer, forming an intermediate material layer, including depositing an intermediate material layer film on a side of the first mask pattern and the first portion of the target layer, and thinning the intermediate material layer film to form the intermediate material layer, forming a second mask pattern that exposes a second portion of the intermediate material layer, removing the exposed second portion of the intermediate material layer to expose the target layer, and patterning the target layer using the first and second mask patterns as patterning masks.

Abstract: There are provided a method of forming a trench for a recessed channel of a transistor and a layout for the same. A layout for the recessed channel according to one aspect of the present invention is formed such that an open region is extended across at least one of a first active region in a lateral direction, and also across another second active region in parallel with the first active region in a diagonal direction, and the extension is cut not to reach an isolation region between two third active regions that are in parallel with the second active region in a diagonal direction, and have noses facing each other in a longitudinal direction, and the layout includes an alignment of a plurality of open regions, which are discontinuously aligned. An etch mask is formed using the layout, and a semiconductor substrate is etched using the etch mask, and a trench for a recessed channel is formed on the active region.

Abstract: A reflective photomask for EUV light is disclosed. The reflective photomask may include a projecting pattern selectively formed on a substrate and a reflective layer on the substrate and the projecting pattern.

Abstract: A photosensitive polymer for a photoresist and a photoresist composition having the same are provided. The photosensitive polymer for a photoresist includes the repeating unit represented by the formula below: wherein R1 is a C1-C20 hydrocarbon group or a C1-C20 hetero hydrocarbon group including at least one hetero atom selected from the group consisting of nitrogen, fluorine and sulfur.

Abstract: DRAM devices include a plurality of word lines extending in a first direction and a plurality of bit lines extending in a second direction and intersecting the word lines. A plurality of active regions is provided that are electrically coupled to the word lines and the bit lines. Each of the active regions defines a single unit memory cell having an area of 6F2 in terms of a minimum line width F. Each of the active regions may be overlapped by only one word line and the active regions may be defined by an isolation region.