Abstract: A method of lithography in a lithographic apparatus configured to transfer a pattern from a patterning device onto a substrate, the method including: determining a dose sensitivity of at least part of the pattern at a plurality of values of a dose, wherein the dose sensitivity is not a monotonically increasing or monotonically decreasing function of the dose. A computer product including a processor, a memory and a storage device, wherein the storage device at least stores values of, or a function describing, a dose sensitivity of at least part of a lithographic pattern at a plurality of values of dose, wherein the dose sensitivity is not a monotonically increasing or monotonically decreasing function of the dose.

Abstract: In an immersion lithography apparatus or device manufacturing method, the position of focus of the projected image is changed during imaging to increase focus latitude. In an embodiment, the focus may be varied using the liquid supply system of the immersion lithographic apparatus.

Abstract: A method is disclosed to form a patterned template on a substrate, to direct orientation of a self-assemblable block copolymer. The method involves providing a resist layer of a positive tone resist on the substrate and overexposing the resist with actinic (e.g. UV) radiation by photolithography to expose a continuous region of the resist layer with a sub-resolution unexposed resist portion at the interface between the resist and the substrate. The resist portion remaining at the interface, after removal of the exposed region, provides a basis for a chemical epitaxy template. The method may allow for simple, direct photolithography to form a patterned chemical epitaxy template and optionally include an accurately co-aligned graphoepitaxy feature and/or a substrate alignment feature.

Abstract: A method to determine an improved configuration for a lithography apparatus, a computer-readable medium for use in carrying out the method, and a lithography apparatus are disclosed. In an example, the method involves intelligent selection of one or more device features to measure and use in a routine to optimize the configuration of the lithography apparatus. According to an example, the method comprises imposing a target error profile to one or more device features for which measurement data is not sufficient, for example in a regions where a selected device feature is sparsely distributed.

Abstract: A method of forming a plurality of regularly spaced lithography features, e.g. contact holes, including: providing a trench on a substrate, the trench having opposing side-walls and a base, with the side-walls having a width therebetween, wherein the trench is formed by photolithography including exposing the substrate using off-axis illumination whereby a modulation is provided to the side-walls of the trench; providing a self-assemblable block copolymer having first and second blocks in the trench; causing the self-assemblable block copolymer to self-assemble into an ordered layer in the trench, the layer having first domains of the first block and second domains of the second block; and selectively removing the first domain to form at least one regularly spaced row of lithography features having the second domain along the trench.

Abstract: A method of optimizing a lithographic process for imaging a pattern, including a plurality of features, onto a substrate using a lithographic apparatus, the lithographic apparatus having a controllable illumination system to illuminate a patterning device and a controllable projection system to project an image of the patterning device onto the substrate, the method including selecting a feature from the plurality of features, determining an illumination setting for the illumination system to optimize imaging of the selected feature, and determining a projection setting for the projection system to optimize imaging of the selected feature taking account of the illumination setting.

Abstract: A method of designing an epitaxy template to direct self-assembly of a block copolymer on a substrate into an ordered target pattern involves providing a primary epitaxy template design and then varying the design to optimize a pattern fidelity statistic, such as placement error, relative to the target pattern by modelling predicted self-assembled block copolymer patterns and optimizing pattern placement as a function of a varied design parameter. In addition to varying a design parameter to optimize the pattern fidelity statistic, a random error in the template design is included prior to modelling predicted patterns in order to compensate for expected template inaccuracy in practice. The inclusion of a realistic random error in the template design, in addition to systematic variation of a design parameter, may improve the template design optimization to render the result less sensitive to error which may be inevitable in practice.

Abstract: A lithographic mask has a substrate substantially transmissive for radiation of a certain wavelength, the substrate having a radiation absorbing material in an arrangement, the arrangement configured to apply a pattern to a cross-section of a radiation beam of the certain wavelength, wherein the absorbing material has a thickness which is substantially equal to the certain wavelength divided by a refractive index of the absorbing material.

Abstract: A lithographic mask has a substrate substantially transmissive for radiation of a certain wavelength, the substrate having a radiation absorbing material in an arrangement, the arrangement configured to apply a pattern to a cross-section of a radiation beam of the certain wavelength, wherein the absorbing material has a thickness which is substantially equal to the certain wavelength divided by a refractive index of the absorbing material.

Abstract: A method is disclosed to form a patterned epitaxy template, on a substrate, to direct self-assembly of block copolymer for device lithography. A resist layer on a substrate is selectively exposed with actinic (e.g. UV or DUV) radiation by photolithography to provide exposed portions in a regular lattice pattern of touching or overlapping shapes arranged to leave unexposed resist portions between the shapes. Exposed or unexposed resist is removed with remaining resist portions providing the basis for a patterned epitaxy template for the orientation of the self-assemblable block copolymer as a hexagonal or square array. The method allows for simple, direct UV lithography to form patterned epitaxy templates with sub-resolution features.

Abstract: A method is disclosed to form a patterned template on a substrate, to direct orientation of a self-assemblable block copolymer. The method involves providing a resist layer of a positive tone resist on the substrate and overexposing the resist with actinic (e.g. UV) radiation by photolithography to expose a continuous region of the resist layer with a sub-resolution unexposed resist portion at the interface between the resist and the substrate. The resist portion remaining at the interface, after removal of the exposed region, provides a basis for a chemical epitaxy template. The method may allow for simple, direct photolithography to form a patterned chemical epitaxy template and optionally include an accurately co-aligned graphoepitaxy feature and/or a substrate alignment feature.

Abstract: In an immersion lithography apparatus or device manufacturing method, the position of focus of the projected image is changed during imaging to increase focus latitude. In an embodiment, the focus may be varied using the liquid supply system of the immersion lithographic apparatus.

Abstract: A graphoepitaxy template to align a self-assembled block polymer adapted to self-assemble into a 2-D array having parallel rows of discontinuous first domains extending parallel to a first axis, mutually spaced along an orthogonal second axis, and separated by a continuous second domain. The graphoepitaxy template has first and second substantially parallel side walls extending parallel to and defining the first axis and mutually spaced along the second axis to provide a compartment to hold at least one row of discontinuous first domains of the self-assembled block copolymer on the substrate between and parallel to the side walls, and separated therefrom by a continuous second domain. The compartment has a graphoepitaxial nucleation feature arranged to locate at least one of the discontinuous first domains at a specific position within the compartment. Methods for forming the graphoepitaxy template and its use for device lithography are also disclosed.

Abstract: A lithographic method includes exposing a first layer of material to a radiation beam to form a first pattern feature in the first layer, the first pattern feature having sidewalls, and a focal property of the radiation beam being controlled to control a sidewall angle of the sidewalls; providing a second layer of material over the first pattern feature to provide a coating on sidewalls of the first pattern; removing a portion of the second layer, leaving a coating of the second layer of material on sidewalls of the first pattern; removing the first pattern formed from the first layer, leaving on the substrate at least a part of the second layer that formed a coating on sidewalls of that first pattern, the part of the second layer left forming second pattern features in locations adjacent to the locations of sidewalls of the removed first pattern feature.

Abstract: In an embodiment, there is provided a method of at least partially compensating for a deviation in a property of a pattern feature to be applied to a substrate using a lithographic apparatus. The method includes determining a desired phase change to be applied to at least a portion of a radiation beam that is to be used to apply the pattern feature to the substrate and which would at least partially compensate for the deviation in the property. The determination of the desired phase change includes determining a desired configuration of a phase modulation element. The method further includes implementing the desired phase change to the portion of the radiation beam when applying the pattern feature to the substrate, the implementation of the desired phase change comprising illuminating the phase modulation element with the portion of the radiation beam when the phase modulation element is in the desired configuration.

Abstract: In an immersion lithography apparatus or device manufacturing method, the position of focus of the projected image is changed during imaging to increase focus latitude. In an embodiment, the focus may be varied using the liquid supply system of the immersion lithographic apparatus.

Abstract: Variables in each step in a double patterning lithographic process are recorded and characteristics of intermediate features in a double patterning process measured. The final feature is then modeled, and the values of the variables optimized.

Abstract: A lithographic apparatus includes a phase adjuster to adjust a phase of an optical wave traversing an optical element of the phase adjuster during exposure of a pattern on a substrate. In use, the pattern is illuminated with an illumination mode including an off-axis radiation beam. This beam is diffracted into a number of first-order diffracted beams, one associated with a first pitch in the pattern, along a first direction, another associated with a second pitch along a different, second direction. An area is identified where the first-order diffracted beam associated with the first pitch traverses the optical element. An image characteristic of an image of the pattern is optimized by calculating a desired optical phase of this first-order diffracted beam in relation to the optical phase of the other first-order diffracted beam. The phase adjuster is controlled to apply the desired optical phase to the first order diffracted beam.

Abstract: A lithographic mask has a substrate substantially transmissive for radiation of a certain wavelength, the substrate having a radiation absorbing material in an arrangement, the arrangement configured to apply a pattern to a cross-section of a radiation beam of the certain wavelength, wherein the absorbing material has a thickness which is substantially equal to the certain wavelength divided by a refractive index of the absorbing material.

Abstract: A method of increasing a depth of focus of a lithographic apparatus is disclosed. The method includes forming diffracted beams of radiation using a patterning device pattern; and transforming a phase-wavefront of a portion of the diffracted beams into a first phase-wavefront having a first focal plane for the lithographic apparatus, and a second phase-wavefront having a second, different focal plane, wherein the transforming comprises: subjecting a phase of a first portion of a first diffracted beam and a phase of a corresponding first portion of a second diffracted beam to a phase change which results in an at least partial formation of the first phase-wavefront, and subjecting a phase of a second portion of the first diffracted beam and a phase of a corresponding second portion of the second diffracted beam to a phase change which results in an at least partial formation of the second phase-wavefront.