Patent application number | Description | Published |
20090233189 | DEVICE AND METHOD FOR OBTAINING EXPOSURE CORRECTION INFORMATION, AND MANUFACTURING METHOD OF SEMICONDUCTOR DEVICE - A method of obtaining exposure correction information includes adjusting intensity of light incident on a photomask so that intensity of light output from the photomask has a desired distribution, and includes obtaining the exposure correction information as a distribution of the adjusted intensity of light incident on the photomask. | 09-17-2009 |
20090317732 | PATTERN VERIFICATION-TEST METHOD, OPTICAL IMAGE INTENSITY DISTRIBUTION ACQUISITION METHOD, AND COMPUTER PROGRAM - A pattern verification-test method according to an embodiment of the present invention includes: deriving an illumination condition at a verification-test subject position in a photomask surface of a mask pattern as a verification or a test subject based on the verification-test subject position and illumination condition information about a distribution of an illumination condition in a photomask surface of exposure light incident on the mask pattern, performing lithography simulation on the mask pattern based on the derived illumination condition and the mask pattern, and verifying or testing the mask pattern based on a result of the lithography simulation. | 12-24-2009 |
20100003830 | IMPRINT MASK MANUFACTURING METHOD, IMPRINT MASK MANUFACTURING DEVICE, AND SEMICONDUCTOR DEVICE MANUFACTURING METHOD - A pattern is formed on a mask substrate. Positional deviation information between an actual position of the pattern formed on the mask substrate and a design position decided at the time of designing the pattern is calculated. A heterogeneous layer of which a volume expands more greatly than that of surrounding mask substrate region is formed in a predetermined position within the mask substrate so that volume expansion of the heterogeneous layer according to the positional deviation information is achieved. | 01-07-2010 |
20100021826 | REFLECTIVE MASK, MANUFACTURING METHOD FOR REFLECTIVE MASK, AND MANUFACTURING METHOD FOR SEMICONDUCTOR DEVICE - A reflective mask comprising: a reflective layer that is arranged on a surface on a side on which EUV light is irradiated and reflects the EUV light; a buffer layer containing Cr that is arranged on a side of the reflective layer on which the EUV light is irradiated and covers an entire surface of the reflective layer; and a non-reflective layer that is arranged on a side of the buffer layer on which the EUV light is irradiated and in which an absorber that absorbs the irradiated EUV light is arranged in a position corresponding to a mask pattern to be reduced and transferred onto a wafer. | 01-28-2010 |
20100032566 | SUBSTRATE SURFACE INSPECTION METHOD AND INSPECTION APPARATUS - A substrate surface inspection method inspects for a defect on a substrate including a plurality of materials on a surface thereof. The inspection method comprises: irradiating the surface of the substrate with an electron beam, a landing energy of the electron beam set such that a contrast between at least two types of materials of the plurality of materials is within a predetermined range; detecting electrons generated by the substrate to acquire a surface image of the substrate, with a pattern formed thereon from the at least two types of materials eliminated or weakened; and detecting the defect from the acquired surface image by detecting as the defect an object image having a contrast by which the object image can be distinguished from a background image in the surface image. Defects present on the substrate surface can be detected easily and precisely by using a cell inspection. | 02-11-2010 |
20100075443 | TEMPLATE INSPECTION METHOD AND MANUFACTURING METHOD FOR SEMICONDUCTOR DEVICE - A template inspection method for performing defect inspection of a template, by bringing a pattern formation surface of a template used to form a pattern close to a first fluid coated on a flat substrate, filling the first fluid into a pattern of the template, and by performing optical observation of the template in a state that the first fluid is sandwiched between the template and the substrate, wherein a difference between an optical constant of the first fluid and an optical constant of the template is larger than a difference between an optical constant of air and the optical constant of the template. | 03-25-2010 |
20120040293 | REFLECTIVE MASK, MANUFACTURING METHOD FOR REFLECTIVE MASK, AND MANUFACTURING METHOD FOR SEMICONDUCTOR DEVICE - A reflective mask comprising: a reflective layer that is arranged on a surface on a side on which EUV light is irradiated and reflects the EUV light; a buffer layer containing Cr that is arranged on a side of the reflective layer on which the EUV light is irradiated and covers an entire surface of the reflective layer; and a non-reflective layer that is arranged on a side of the buffer layer on which the EUV light is irradiated and in which an absorber that absorbs the irradiated EUV light is arranged in a position corresponding to a mask pattern to be reduced and transferred onto a wafer. | 02-16-2012 |
20120091370 | IMPRINT MASK MANUFACTURING METHOD, IMPRINT MASK MANUFACTURING DEVICE, AND SEMICONDUCTOR DEVICE MANUFACTURING METHOD - A pattern is formed on a mask substrate. Positional deviation information between an actual position of the pattern formed on the mask substrate and a design position decided at the time of designing the pattern is calculated. A heterogeneous layer of which a volume expands more greatly than that of surrounding mask substrate region is formed in a predetermined position within the mask substrate so that volume expansion of the heterogeneous layer according to the positional deviation information is achieved. | 04-19-2012 |
20120250011 | PATTERN VERIFICATION-TEST METHOD, OPTICAL IMAGE INTENSITY DISTRIBUTION ACQUISITION METHOD, AND COMPUTER PROGRAM - A pattern verification-test method according to an embodiment of the present invention includes: deriving an illumination condition at a verification-test subject position in a photomask surface of a mask pattern as a verification or a test subject based on the verification-test subject position and illumination condition information about a distribution of an illumination condition in a photomask surface of exposure light incident on the mask pattern, performing lithography simulation on the mask pattern based on the derived illumination condition and the mask pattern, and verifying or testing the mask pattern based on a result of the lithography simulation. | 10-04-2012 |
20130153791 | Mask Manufacturing Device - According to one embodiment, a mask manufacturing device includes a positional-deviation calculating unit that acquires positional deviation information between an actual position of a pattern formed on a mask substrate and a design position decided at the time of designing the pattern to a predetermined area of a square on the mask substrate; an irradiating-condition calculating unit that calculates an irradiating condition including an irradiating amount and an irradiating position of radiation to correct the positional deviation calculated to the predetermined area of a square on the mask substrate by using positional-deviation correction information, which indicates a relationship between the irradiating amount and the irradiating position of the radiation to the mask substrate and a pattern position change after irradiation of the radiation; and an irradiating unit that irradiates the mask substrate with the radiation under the irradiating condition calculated by the irradiating-condition calculating unit. | 06-20-2013 |
20130157473 | Mask Manufacturing Device - According to one embodiment, a mask manufacturing method includes acquiring positional deviation information between an actual position of a pattern formed on a mask substrate and a design position decided at the time of designing the pattern; calculating an irradiating amount and an irradiating position of radiation to be irradiated to a predetermined area of a square on the mask substrate according to the calculated positional deviation information; and irradiating the radiation based on the calculated irradiating amount and the calculated irradiating position to form in a part of the mask substrate a heterogeneous layer of which volume is expanded more greatly than that of the surrounding mask substrate region. | 06-20-2013 |