Patent Number: 
Section: claims

1. A method for designing a phase shift mask, having a substrate (200) with a transparent property, and an opaque layer (100) formed on said substrate and having an opaque property, wherein a plurality of rectangular apertures are formed in said opaque layer, a two-dimensional layout pattern is formed by opaque parts (120) comprising regions at which said opaque layer is formed, and transparent parts (110) comprising regions at which said apertures are formed, and for a pair of adjacently disposed apertures, so that a phase of light transmitted through one of said pair of adjacent apertures will be shifted by 180 degrees with respect to a phase of light transmitted through other of said pair of adjacent apertures, a trench (220), having a predetermined depth and an outline greater than an outline of said one aperture, is formed on a portion of said substrate at which said one aperture is formed,said phase shift mask designing method comprising the steps of:a two-dimensional layout designing step (S1) of defining an XY plane on a surface of said substrate, determining a width Wx in an X-axis direction and a width Wy in a Y-axis direction of an aperture and a width Ws of an opaque part, and positioning a plurality of apertures of a same size at least along the X-axis to thereby design a two-dimensional layout on said XY plane;a three-dimensional structure determination step (S2) of determining, for each of said plurality of apertures, whether or not phase shifting is to be performed and determining, for the apertures with which phase shifting is to be performed, a trench depth d and an undercut amount Uc, which indicates a distance between a position of an outline of the trench and a position of the outline of the aperture, to thereby determine a three-dimensional structure;a three-dimensional analysis step (S3) of using a three-dimensional structural body, which is defined by said two-dimensional layout designing step and said three-dimensional structure determination step, to determine a light intensity deviation D, which indicates, for a case where light is transmitted under same exposure conditions through a pair of adjacent apertures that have been designed to realize a phase shift of 180 degrees with respect to each other, a deviation in intensities of light transmitted through the respective apertures;a two-dimensional analysis step (S4) of using a two-dimensional structural body, which is defined by said two-dimensional layout, to determine, in a case where, for said pair of adjacent apertures, a light transmittance of one aperture is set to 100% and a light transmittance of the other aperture is set to T %, a transmittance T such that a deviation in intensities of light transmitted through each of said pair of adjacent apertures will be equal to said light intensity deviation D; anda layout correction step (S5) of correcting said two-dimensional layout based on said transmittance T. 2. The phase shift mask designing method as set forth in claim 1, whereinin the two-dimensional analysis step, a light intensity deviation D is determined for each of a plurality of transmittances and a transmittance, which provides a result matching the light intensity deviation D determined in the three-dimensional analysis step, is determined as the transmittance T. 3. The phase shift mask designing method as set forth in claim 2, whereinin the two-dimensional analysis step, a database, with which a value of the light intensity deviation D is determined for each of various different combinations of parameter values of the width Wx in the X-direction of an aperture, the width Ws of an opaque part, and the transmittance T, is prepared in advance, and in determining a light intensity deviation D for a specific two-dimensional structural body, said database is searched to determine the light intensity deviation D. 4. The phase shift mask designing method as set forth in claim 3, whereina database, having the width Wy in the Y-axis direction of an aperture in addition as a parameter value, is prepared. 5. The phase shift mask designing method as set forth in claim 3, whereinin a case where a combination of parameter values that matches search conditions does not exist among combinations of parameters prepared inside the database, an interpolation operation using parameter values that are close is performed. 6. The phase shift mask designing method as set forth in claim 3, whereinin the two-dimensional layout designing step, a plurality of apertures are positioned in two-dimensional matrix form in the X-axis direction and the Y-axis direction, and as the width Ws of the opaque parts, two parameters of a width Wsx in the X-axis direction of an opaque part existing between apertures that are adjacent in the X-axis direction and a width Wsy in the Y-axis direction of an opaque part existing between apertures that are adjacent in the Y-axis direction are used. 7. The phase shift mask designing method as set forth in claim 1, whereinin the three-dimensional analysis step, a database, with which a value of the light intensity deviation D is determined for each of various different combinations of parameter values of the width Wx in the X-direction of an aperture, the width Ws of an opaque part, and the undercut amount Uc, is prepared in advance, and in determining a light intensity deviation D for a specific three-dimensional structural body, said database is searched to determine the light intensity deviation D. 8. The phase shift mask designing method as set forth in claim 1, whereinin the layout correction step, a database, with which an optimal correction amount δ is determined for each of various different combinations of parameter values of the width Wx in the X-direction of an aperture, the width Ws of an opaque part, and the transmittance T, is prepared in advance, and in performing a correction of a specific two-dimensional layout, with which a specific transmittance is defined, said database is searched to determine the optimal correction amount δ. 9. The phase shift mask designing method as set forth in claim 1, whereinin the three-dimensional structure determination step, apertures with which phase shifting is to be performed are determined so that every other aperture of the plurality of apertures that are positioned along the X-axis direction or the Y-axis direction are selected. 10. The phase shift mask designing method as set forth in claim 1, whereina part or all of the process of determining the light intensity deviation D in the three-dimensional analysis step, the process of determining the transmittance T in the two-dimensional analysis step, and the correction process in the layout correction step are executed using computer simulation. 11. The phase shift mask designing method as set forth in claim 1, whereina part or all of the process of determining the light intensity deviation D in the three-dimensional analysis step, the process of determining the transmittance T in the two-dimensional analysis step, and the correction process in the layout correction step are executed by experimentation using an actually manufactured phase shift mask. 12. A device for designing a phase shift mask, having a substrate (200) with a transparent property, and an opaque layer (100) formed on said substrate and having an opaque property, wherein a plurality of rectangular apertures are formed in said opaque layer, a two-dimensional layout pattern is formed by opaque parts (120) comprising regions at which said opaque layer is formed, and transparent parts (110) comprising regions at which said apertures are formed, and for a pair of adjacently disposed apertures, so that a phase of light transmitted through one of said pair of adjacent apertures will be shifted by 180 degrees with respect to a phase of light transmitted through another of said pair of adjacent apertures, a trench (220), having a predetermined depth and an outline greater than an outline of said one aperture, is formed on a portion of said substrate at which said one aperture is formed,said phase shift mask designing device comprising:a two-dimensional layout determination tool (10), which, based on instructions from an operator, determines a width Wx in an X-axis direction and a width Wy in a Y-axis direction of an aperture and a width Ws of an opaque part on an XY plane defined on a surface of said substrate and positions a plurality of apertures of a same size at least along the X-axis to determine a two-dimensional layout on said XY plane;a three-dimensional structure determination tool (20), which, based on instructions from an operator, determines whether or not phase shifting is to be performed for each of the plurality of apertures and determines, for apertures with which phase shifting is to be performed, a trench depth d and an undercut amount Uc, which indicates a distance between a position of an outline of the trench and a position of an outline of the aperture, to thereby determine a three-dimensional structure;a three-dimensional simulator (30), which performs a three-dimensional analysis process of executing a three-dimensional simulation using a three-dimensional structural body, which is defined by said two-dimensional layout determination tool and said three-dimensional structure determination tool, as a model to determine a light intensity deviation D that indicates a deviation of intensities of light transmitted through each of a pair of adjacent apertures, designed to realize a phase shift of 180 degrees with respect to each other, when light is transmitted through the apertures under same exposure conditions; anda two-dimensional simulator (40), which performs a two-dimensional analysis process of executing two-dimensional simulations using a two-dimensional structural body, which is defined by said two-dimensional layout, as a model to determine a transmittance T, such that, when for a pair of adjacent apertures, a light transmittance of one aperture is set to 100% and a light transmittance of another aperture is set to T %, a deviation in intensities of light transmitted through each of said pair of adjacent apertures becomes equal to said light intensity deviation D, and performs a layout correction process of executing two-dimensional simulations using a model, with which said transmittance T is applied to the two-dimensional structural body defined by said two-dimensional layout, to correct said two-dimensional layout. 13. The phase shift mask designing device as set forth in claim 12 whereinwhen the two-dimensional simulator performs the two-dimensional analysis process, a light intensity deviation D is determined for each of a plurality of transmittances, and a transmittance, which provides a result matching the light intensity deviation D determined by the three-dimensional analysis process performed by the three-dimensional simulator, is determined as the transmittance T. 14. The phase shift mask designing device as set forth in claim 12, wherein:a database (55), in which light intensity deviations D, each defined as a value that indicates a deviation of intensities of light transmitted through each of a pair of adjacent apertures, which are of a predetermined three-dimensional structural body and are designed to realize a phase shift of 180 degrees with respect to each other, when light is transmitted through the apertures under the same conditions, are stored according to various different combinations of parameter values of the width Wx in the X-direction of an aperture, the width Ws of an opaque part, and the undercut amount Uc; anda light intensity deviation determination tool (50), which determines a specific light intensity deviation D by searching said database using specific parameter values determined by the two-dimensional layout determination tool and the three-dimensional structure determination tool;are provided as an alternative means to the three-dimensional simulator. 15. The phase shift mask designing device as set forth in claim 14, whereina database, having the width Wy in the Y-axis direction of an aperture in addition as a parameter value, is prepared. 16. The phase shift mask designing device as set forth in claim 14, whereinin order to accommodate for a two-dimensional layout, with which a plurality of apertures are positioned in two-dimensional matrix form in the X-axis direction and the Y-axis direction, two parameters of a width Wsx in the X-axis direction of an opaque part existing between apertures that are adjacent in the X-axis direction and a width Wsy in the Y-axis direction of an opaque part existing between apertures that are adjacent in the Y-axis direction are used as parameter values in the database as the width Ws of the opaque parts. 17. The phase shift mask designing device as set forth in claim 14, whereinin a case where a combination of parameter values that matches search conditions does not exist among combinations of parameters prepared inside the database, the light intensity deviation determination tool, transmittance determination tool, or correction amount determination tool performs an interpolation operation using parameter values that are close to determine the light intensity deviation D, transmittance T, or correction amount δ. 18. The phase shift mask designing device as set forth in claim 12, wherein:a database (65), in which light intensity deviations D, each defined as a value that indicates a deviation of intensities of light transmitted through each of a pair of adjacent apertures, which are of a predetermined two-dimensional structural body and with which a transmittance of one has been set to 100% and a transmittance of the other has been set to T %, when light is transmitted through the apertures under the same conditions, are stored according to various different combinations of parameter values of the width Wx in the X-direction of an aperture, the width Ws of an opaque part, and the transmittance T; anda transmittance determination tool (60), which searches said database using specific parameter values determined by the two-dimensional layout determination tool and a specific light intensity deviation D determined by the three-dimensional simulator to determine a transmittance T, by which a light intensity deviation equal to said specific light intensity deviation D is obtained;are provided as an alternative means to the two-dimensional simulator for executing the two-dimensional analysis process. 19. The phase shift mask designing device as set forth in claim 12, wherein:a database (75), in which correction amounts δ, each of which concerns widths of the respective apertures and is required to make equal the intensities of light transmitted under the same conditions through each of a pair of adjacent apertures, which are of a predetermined two-dimensional structural body, are of the same size, and with which a transmittance of one has been set to 100% and a transmittance of the other has been set to T %, are stored according to various different combinations of parameter values of the width Wx in the X-direction of an aperture, the width Ws of an opaque part, and the transmittance T; anda correction amount determination tool (70), which searches said database using specific parameter values determined by the two-dimensional layout determination tool and a specific transmittance T determined by the two-dimensional analysis process performed by the two-dimensional simulator to determine a correction amount δ for said two-dimensional layout;are provided as an alternative means to the two-dimensional simulator for executing the layout correction process. 20. A device for designing a phase shift mask, having a substrate (200) with a transparent property, and an opaque layer (100) formed on said substrate and having an opaque property, wherein a plurality of rectangular apertures are formed in said opaque layer, a two-dimensional layout pattern is formed by opaque parts (120) comprising regions at which said opaque layer is formed, and transparent parts (110) comprising regions at which said apertures are formed, and for a pair of adjacently disposed apertures, so that a phase of light transmitted through one of said pair of adjacent apertures will be shifted by 180 degrees with respect to a phase of light transmitted through another of said pair of adjacent apertures, a trench (220), having a predetermined depth and an outline greater than an outline of said one aperture, is formed on a portion of said substrate at which said one aperture is formed,said phase shift mask designing device comprising:a two-dimensional layout determination tool (10), which, based on instructions from an operator, determines a width Wx in an X-axis direction and the width Wy in a Y-axis direction of an aperture and a width Ws of an opaque part on an XY plane defined on a surface of said substrate and positions a plurality of apertures of a same size at least along the X-axis to determine a two-dimensional layout on said XY plane;a three-dimensional structure determination tool (20), which, based on instructions from an operator, determines whether or not phase shifting is to be performed for each of the plurality of apertures and determines, for apertures with which phase shifting is to be performed, a trench depth d and an undercut amount Uc, which indicates a distance between a position of an outline of the trench and a position of an outline of the aperture, to thereby determine a three-dimensional structure;a first database (55), in which light intensity deviations D, each defined as a value that indicates a deviation of intensities of light transmitted through each of a pair of adjacent apertures, which are of a predetermined three-dimensional structural body and are designed to realize a phase shift of 180 degrees with respect to each other, when light is transmitted through the apertures under same conditions, are stored according to various different combinations of parameter values of the width Wx in the X-direction of an aperture, the width Ws of an opaque part, and the undercut amount Uc;a light intensity deviation determination tool (50), which determines a specific light intensity deviation D by searching said first database using specific parameter values determined by said two-dimensional layout determination tool and said three-dimensional structure determination tool;a second database (65), in which light intensity deviations D, each defined as a value that indicates a deviation of intensities of light transmitted through each of a pair of adjacent apertures, which are of a predetermined two-dimensional structural body and with which a transmittance of one has been set to 100% and a transmittance of the other has been set to T %, when light is transmitted through the apertures under the same conditions, are stored according to various different combinations of parameter values of the width Wx in the X-direction of an aperture, the width Ws of an opaque part, and the transmittance T;a transmittance determination tool (60), which searches said second database using specific parameter values determined by said two-dimensional layout determination tool and a specific light intensity deviation D determined by said light intensity deviation determination tool to determine a transmittance T, by which a light intensity deviation equal to said specific light intensity deviation D is obtained;a third database (75), in which correction amounts δ, each of which concerns widths of the respective apertures and is required to make equal the intensities of light transmitted under the same conditions through each of a pair of adjacent apertures, which are of a predetermined two-dimensional structural body, are of the same size, and with which a transmittance of one has been set to 100% and a transmittance of the other has been set to T %, are stored according to various different combinations of parameter values of the width Wx in the X-direction of an aperture, the width Ws of an opaque part, and the transmittance T; anda correction amount determination tool (70), which searches said third database using specific parameter values determined by said two-dimensional layout determination tool and a specific transmittance T determined by said transmittance determination tool to determine a correction amount S for said two-dimensional layout.