Abstract: A method for transferring a fractured pattern decomposed into elementary shapes, onto a substrate by direct writing by a particle or photon beam, comprises a step of identifying at least one elementary shape of the fractured pattern, called removable elementary shape, whose removal induces modifications of the transferred pattern within a preset tolerance envelope; a step of removing the removable shape or shapes from the fractured pattern to obtain a modified fractured pattern; and an exposure step, comprising exposing the substrate to a plurality of shots of a shaped particle or photon beam, each shot corresponding to an elementary shape of the modified fractured pattern. A computer program product for carrying out such a method is provided.

Abstract: A computer implemented method of fracturing free form target design into elementary shots for defined roughness of the contour comprises determining a first set of shots which pave the target design and determining a second set of shots to fill the gaps. The dose levels of overlapping shots in the first or second sets of shots are determined so the compounded dose is adequate to the resist threshold, considering the proximity effect of the actual imprint of shots on the insulated target. A dose geometry modulation is applied and rounded shot prints are produced by shots not circular that may overlap. The degree of overlap is determined as a function of desired optimization of fit criteria between a printed contour and the contour of the desired pattern. Placements and dimensions of the shots are determined by a plurality of fit criteria between printed contour and contour of the desired pattern.

Abstract: A method for transferring a fractured pattern decomposed into elementary shapes, onto a substrate by direct writing by a particle or photon beam, comprises a step of identifying at least one elementary shape of the fractured pattern, called removable elementary shape, whose removal induces modifications of the transferred pattern within a preset tolerance envelope; a step of removing the removable shape or shapes from the fractured pattern to obtain a modified fractured pattern; and an exposure step, comprising exposing the substrate to a plurality of shots of a shaped particle or photon beam, each shot corresponding to an elementary shape of the modified fractured pattern. A computer program product for carrying out such a method is provided.

Abstract: A method of electron-beam lithography by direct writing solves the reliability of design of etched components through rounding of the corners of contiguous patterns, notably in patterns to be etched of critical dimension of the order of 35 nm. The method determines critical patterns, and correction patterns by subtracting patterns of corrections of dimensions and of locations as a function of rounding of external or internal corners to be corrected and etching of the corrected design. The corrections may be by a correction model taking account of the parameters of the critical patterns. A correction of the proximity effects specific to these methods is also performed, by resizing of edges of blocks to be etched in combination optimized by the energy latitude with a modulation of the radiated doses. A rescaling and negation functions and eRIF functions may be used to optimize the parameters and the realization of the extrusion.

Abstract: A computer implemented method of fracturing free form target design into elementary shots for defined roughness of the contour comprises determining a first set of shots which pave the target design and determining a second set of shots to fill the gaps. The dose levels of overlapping shots in the first or second sets of shots are determined so the compounded dose is adequate to the resist threshold, considering the proximity effect of the actual imprint of shots on the insulated target. A dose geometry modulation is applied and rounded shot prints are produced by shots not circular that may overlap. The degree of overlap is determined as a function of desired optimization of fit criteria between a printed contour and the contour of the desired pattern. Placements and dimensions of the shots are determined by a plurality of fit criteria between printed contour and contour of the desired pattern.

Abstract: A lithography method for a pattern to be etched on a support, notably to a method using electron radiation with direct writing on the support. Hitherto, the methods for correcting the proximity effects for dense network geometries (line spacings of 10 to 30 nm) have been reflected in a significant increase in the radiated doses and therefore in the exposure time. According to the invention, the patterns to be etched are modified as a function of the energy latitude of the process, which allows a reduction of the radiated doses.

Abstract: A lithography method based on the projection of cells, notably direct-write electron-beam lithography. One of the main limitations of the methods of this type in the prior art is the writing time. To overcome this limitation, according to the method of the invention, the size of the cells is increased to the maximum aperture of the lithography device. Advantageously, this size increase is obtained by modifying the size of the apertures of the projection stencil level closest to the substrate to be etched. Advantageously, a strip is added to the outside of the block to be etched onto which is radiated a dose calculated to optimize the process energy latitude. Advantageously, this strip is spaced apart from the edge of the block to be etched. Advantageously, the projected cells are not adjoining.

Abstract: A method of electron-beam lithography is provided, notably for technologies of critical dimension of the order of 22 nm. In such methods applied notably to networks of lines, the methods of the prior art do not offer precise and efficient correction of the shortenings of line ends. The method provided solves this problem by carrying out the insertion of contrast intensification structures of types which are optimized for the structure of the lines to be corrected. The method allows the semi-automatic or automatic calculation of the dimensions and locations of said structures. Advantageously, these calculations may be modeled to produce a target design, derived from libraries of components. They may be supplemented with a joint optimization of the size of the etchings and of the radiated doses, as a function of the process energy latitude.

Abstract: A lithography method for a pattern to be etched on a support, notably to a method using electron radiation with direct writing on the support. Hitherto, the methods for correcting the proximity effects for dense network geometries (line spacings of 10 to 30 nm) have been reflected in a significant increase in the radiated doses and therefore in the exposure time. According to the invention, the patterns to be etched are modified as a function of the energy latitude of the process, which allows a reduction of the radiated doses.

Abstract: A lithography method based on the projection of cells, notably direct-write electron-beam lithography. One of the main limitations of the methods of this type in the prior art is the writing time. To overcome this limitation, according to the method of the invention, the size of the cells is increased to the maximum aperture of the lithography device. Advantageously, this size increase is obtained by modifying the size of the apertures of the projection stencil level closest to the substrate to be etched. Advantageously, a strip is added to the outside of the block to be etched onto which is radiated a dose calculated to optimize the process energy latitude. Advantageously, this strip is spaced apart from the edge of the block to be etched.

Abstract: A method of electron-beam lithography is provided, notably for technologies of critical dimension of the order of 22 nm. In such methods applied notably to networks of lines, the methods of the prior art do not offer precise and efficient correction of the shortenings of line ends. The method provided solves this problem by carrying out the insertion of contrast intensification structures of types which are optimized for the structure of the lines to be corrected. The method allows the semi-automatic or automatic calculation of the dimensions and locations of said structures. Advantageously, these calculations may be modeled to produce a target design, derived from libraries of components. They may be supplemented with a joint optimization of the size of the etchings and of the radiated doses, as a function of the process energy latitude.

Abstract: A method of electron-beam lithography by direct writing solves the reliability of design of etched components through rounding of the corners of contiguous patterns, notably in patterns to be etched of critical dimension of the order of 35 nm. The method determines critical patterns, and correction patterns by subtracting patterns of corrections of dimensions and of locations as a function of rounding of external or internal corners to be corrected and etching of the corrected design. The corrections may be by a correction model taking account of the parameters of the critical patterns. A correction of the proximity effects specific to these methods is also performed, by resizing of edges of blocks to be etched in combination optimized by the energy latitude with a modulation of the radiated doses. A rescaling and negation functions and eRIF functions may be used to optimize the parameters and the realization of the extrusion.

Abstract: A method is for producing an asymmetric architecture semiconductor device. The device includes a substrate, and in stacked relation, a first photosensitive layer, a non-photosensitive layer, and a second photosensitive layer. The method includes a first step of exposing a first zone in each of the photosensitive layers by a first beam of electrons traversing the non-photosensitive layer. A second step includes exposing at least one second zone of one of the two photosensitive layers by a second beam of electrons or photons or ions, thereby producing a widening of one of the first zones compared to the other first zone such that the second zone is in part superimposed on one of the first zones.

Abstract: A method for transferring a predetermined pattern onto a flat support performed by direct writing by means of a particle beam comprises at least: deposition of a photoresist layer on a free surface of the support, application of the beam on exposed areas of the photoresist layer, performing correction by modulation of exposure doses received by each exposed area, developing of the photoresist layer so as to form said pattern. Correction further comprises determination of a substitution pattern (11) comprising at least one subresolution feature and use of the substitution pattern (11) for determining the areas to be exposed when the electron beam is applied. In addition, modulation takes account of the density of the substitution pattern (11) near to each exposed area.

Abstract: A method for transferring a predetermined pattern onto a flat support performed by direct writing by means of a particle beam comprises at least: deposition of a photoresist layer on a free surface of the support, application of the beam on exposed areas of the photoresist layer, performing correction by modulation of exposure doses received by each exposed area, developing of the photoresist layer so as to form said pattern. Correction further comprises determination of a substitution pattern (11) comprising at least one subresolution feature and use of the substitution pattern (11) for determining the areas to be exposed when the electron beam is applied. In addition, modulation takes account of the density of the substitution pattern (11) near to each exposed area.

Abstract: A method is for producing an asymmetric architecture semi-conductor device. The device includes a substrate, and in stacked relation, a first photosensitive layer, a non-photosensitive layer, and a second photosensitive layer. The method includes a first step of exposing a first zone in each of the photosensitive layers by a first beam of electrons traversing the non-photosensitive layer. A second step includes exposing at least one second zone of one of the two photosensitive layers by a second beam of electrons or photons or ions, thereby producing a widening of one of the first zones compared to the other first zone such that the second zone is in part superimposed on one of the first zones.

Abstract: An initial layout of an integrated circuit device is separated into a set of definitions for use in a multiple exposure fabrication process. The separation begins with reading a portion of the initial layout and identifying one or more target features within the initial layout. Further, a first revised layout definition is created for a first mask and a second revised layout definition is created for a second mask. The first revised layout definition includes the target features inside the dark-field content. In addition, in one embodiment, the first revised layout definition includes clear areas around each target feature. The second layout definition includes one or more dark features inside the bright-field content. These dark features, when used in the multiple exposure fabrication process, will overlap the target features. The first and second masks may be binary masks, attenuated phase-shifting masks (PSMs) or a combination of a binary mask and an attenuated PSM.

Abstract: An initial layout of an integrated circuit device is separated into a set of definitions for use in a multiple exposure fabrication process. The separation begins with reading a portion of the initial layout and identifying one or more target features within the initial layout. Further, a first revised layout definition is created for a first mask and a second revised layout definition is created for a second mask. The first revised layout definition includes the target features inside the dark-field content. In addition, in one embodiment, the first revised layout definition includes clear areas around each target feature. The second layout definition includes one or more dark features inside the brightfield content. These dark features, when used in the multiple exposure fabrication process, will overlap the target features. The first and second masks may be binary masks, attenuated phase-shifting masks (PSMs) or a combination of a binary mask and an attenuated PSM.

Abstract: A method of illuminating a layer of a material, in particular a photosensitive resin, using a light source, in order to expose an area of that material to a useful dose of light for subsequent etching of that material in that area, consisting in effecting a first exposure through a pattern of a first mask made up of a central hole and peripheral holes with a first dose of light less than said useful dose, and a second exposure through a pattern of a second mask made up of a single hole with a second dose of light such that the cumulative total of said first dose induced through the central hole of the first mask and the second dose induced through the single hole of said second mask produces at least said useful dose over said area.