Abstract: A method of processing a substrate includes forming first photoresist on a substrate. A portion of the first photoresist is selectively exposed to actinic energy and then the first photoresist is negative tone developed to remove an unexposed portion of the first photoresist. Second photoresist is formed on the substrate over the developed first photoresist. A portion of the second photoresist is selectively exposed to actinic energy and then the second photoresist is negative tone developed to remove an unexposed portion of the second photoresist and form a pattern on the substrate which comprises the developed first photoresist and the developed second photoresist. Other implementations are disclosed.

Abstract: A method for reducing the effects of lens heating of a lens in an imaging process includes determining heat load locations on the lens according to an illumination source and a reticle design, obtaining a lens response characterization according to the heat load locations, and utilizing the heat load locations and the lens response characterization to generate a lens heating sensitivity map.

Abstract: A reticle with a composite polarizer includes: a transparent substrate; a patterned layer disposed on said transparent substrate; and a polarizing filter disposed on said transparent substrate, wherein said transparent substrate is substantially transparent with respect to illumination light, said patterned layer is partially opaque with respect to said illumination light, and said polarizing filter is capable of selectively polarizing said illumination light.

Abstract: Methods of forming resist features, resist patterns, and arrays of aligned, elongate resist features are disclosed. The methods include addition of a compound, e.g., an acid or a base, to at least a lower surface of a resist to alter acidity of at least a segment of one of an exposed, acidic resist region and an unexposed, basic resist region. The alteration, e.g., increase or decrease, in the acidity shifts an acid-base equilibrium to either encourage or discourage development of the segment. Such “chemical proximity correction” techniques may be used to enhance the acidity of an exposed, acidic resist segment, to enhance the basicity of an unexposed, basic resist segment, or to effectively convert an exposed, acidic resist segment to an unexposed, basic resist segment or vice versa. Thus, unwanted line breaks, line merges, or misalignments may be avoided.

Abstract: Some embodiments include methods of forming patterns. A semiconductor substrate is formed to comprise an electrically insulative material over a set of electrically conductive structures. An interconnect region is defined across the electrically conductive structures, and regions on opposing sides of the interconnect region are defined as secondary regions. A two-dimensional array of features is formed over the electrically insulative material. The two-dimensional array extends across the interconnect region and across the secondary regions. A pattern of the two-dimensional array is transferred through the electrically insulative material of the interconnect region to form contact openings that extend through the electrically insulative material and to the electrically conductive structures, and no portions of the two-dimensional array of the secondary regions is transferred into the electrically insulative material.

Abstract: An imaging device comprising a first region and a second region. Imaging features in the first region and assist features in the second region are substantially the same size as one another and are formed substantially on pitch. Methods of forming an imaging device and methods of forming a semiconductor device structure are also disclosed.

Abstract: Methods of forming a patterned, silicon-enriched developable antireflective material. One such method comprises forming a silicon-enriched developable antireflective composition. The silicon-enriched developable antireflective composition comprises a silicon-enriched polymer and a crosslinking agent. The silicon-enriched polymer and the crosslinking agent are reacted to form a silicon-enriched developable antireflective material that is insoluble and has at least one acid-sensitive moiety. A positive-tone photosensitive material, such as a positive-tone photoresist, is formed over the silicon-enriched developable antireflective material and regions thereof are exposed to radiation. The exposed regions of the positive-tone photosensitive material and underlying regions of the silicon-enriched developable antireflective material are removed. Additional methods are disclosed, as are semiconductor device structures including a silicon-enriched developable antireflective material.

Abstract: Some embodiments include methods of forming patterns. A semiconductor substrate is formed to comprise an electrically insulative material over a set of electrically conductive structures. An interconnect region is defined across the electrically conductive structures, and regions on opposing sides of the interconnect region are defined as secondary regions. A two-dimensional array of features is formed over the electrically insulative material. The two-dimensional array extends across the interconnect region and across the secondary regions. A pattern of the two-dimensional array is transferred through the electrically insulative material of the interconnect region to form contact openings that extend through the electrically insulative material and to the electrically conductive structures, and no portions of the two-dimensional array of the secondary regions is transferred into the electrically insulative material.

Abstract: An imaging device comprising at least one array pattern region and at least one attenuation region. A plurality of imaging features in the at least one array pattern region and a plurality of assist features in the at least one attenuation region are substantially the same size as one another and are formed substantially on pitch. Methods of forming an imaging device and methods of forming a semiconductor device structure are also disclosed.

Abstract: A method of processing a substrate includes forming first photoresist on a substrate. A portion of the first photoresist is selectively exposed to actinic energy and then the first photoresist is negative tone developed to remove an unexposed portion of the first photoresist. Second photoresist is formed on the substrate over the developed first photoresist. A portion of the second photoresist is selectively exposed to actinic energy and then the second photoresist is negative tone developed to remove an unexposed portion of the second photoresist and form a pattern on the substrate which comprises the developed first photoresist and the developed second photoresist. Other implementations are disclosed.

Abstract: Some embodiments include system and methods to obtain information for adjusting variations in features formed on a substrate of a semiconductor device. Such methods can include determining a first pupil in an illumination system used to form a first feature, and determining a second pupil used to form a second feature. The methods can also include determining a pupil portion belonging to only one of the pupils, and generating a modified pupil portion from the pupil portion. Information associated with the modified pupil portion can be obtained for controlling a portion of a projection lens assembly of an illumination system. Other embodiments are described.

Abstract: A method for reducing the effects of lens heating of a lens in an imaging process includes determining heat load locations on the lens according to an illumination source and a reticle design, obtaining a lens response characterization according to the heat load locations, and utilizing the heat load locations and the lens response characterization to generate a lens heating sensitivity map.

Abstract: Methods of forming a patterned, silicon-enriched developable antireflective material. One such method comprises forming a silicon-enriched developable antireflective composition. The silicon-enriched developable antireflective composition comprises a silicon-enriched polymer and a crosslinking agent. The silicon-enriched polymer and the crosslinking agent are reacted to form a silicon-enriched developable antireflective material that is insoluble and has at least one acid-sensitive moiety. A positive-tone photosensitive material, such as a positive-tone photoresist, is formed over the silicon-enriched developable antireflective material and regions thereof are exposed to radiation. The exposed regions of the positive-tone photosensitive material and underlying regions of the silicon-enriched developable antireflective material are removed. Additional methods are disclosed, as are semiconductor device structures including a silicon-enriched developable antireflective material.

Abstract: An imaging device comprising at least one array pattern region and at least one attenuation region. A plurality of imaging features in the at least one array pattern region and a plurality of assist features in the at least one attenuation region are substantially the same size as one another and are formed substantially on pitch. Methods of forming an imaging device and methods of forming a semiconductor device structure are also disclosed.

Abstract: A method of mitigating asymmetric lens heating in photolithographically patterning a photo-imagable material using a reticle includes determining where first hot spot locations are expected to occur on a lens when using a reticle to pattern a photo-imagable material. The reticle is then fabricated to include non-printing features within a non-printing region of the reticle which generate additional hot spot locations on the lens when using the reticle to pattern the photo-imagable material. Other implementations are contemplated, including reticles which may be independent of method of use or fabrication.

Abstract: Photolithographic apparatus and methods are disclosed. One such apparatus includes an optical path configured to provide a first diffraction pattern in a portion of an optical system and to provide a second diffraction pattern to the portion of the optical system after providing the first diffraction pattern. Meanwhile, one such method includes providing a first diffraction pattern onto a portion of an optical system, wherein a semiconductor article is imaged using the first diffraction pattern. A second diffraction pattern is also provided onto the portion of the optical system, but the second diffraction pattern is not used to image the semiconductor article.

Abstract: Some embodiments include methods of forming patterns. A semiconductor substrate is formed to comprise an electrically insulative material over a set of electrically conductive structures. An interconnect region is defined across the electrically conductive structures, and regions on opposing sides of the interconnect region are defined as secondary regions. A two-dimensional array of features is formed over the electrically insulative material. The two-dimensional array extends across the interconnect region and across the secondary regions. A pattern of the two-dimensional array is transferred through the electrically insulative material of the interconnect region to form contact openings that extend through the electrically insulative material and to the electrically conductive structures, and no portions of the two-dimensional array of the secondary regions is transferred into the electrically insulative material.

Abstract: A method of forming a reversed pattern in a substrate. A resist on a substrate is exposed and developed to form a pattern therein, the patterned resist having a first polarity. The polarity of the patterned resist is reversed to a second polarity, and a reversal film is formed over the patterned resist having the second polarity. The patterned resist having the second polarity is removed, forming a pattern in the reversal film. The pattern in the reversal film is then transferred to the substrate. Additional methods of forming a reversed pattern in a substrate are disclosed, as is a semiconductor structure formed during the methods.

Abstract: A method for producing polymers with controlled molecular weight and desired end functionalities and the resulting polymers. The method comprises a) forming a microemulsion comprising monomer, water, and an effective amount of an effective surfactant, b) adding to the microemulsion an amount of a water-soluble photo-initiator system wherein the initiator system produces one type of monomer-soluble radical active centers and wherein the radical active centers contain desired end group functionalities for a polymer or oligomer, and c) illuminating the microemulsion to photoinitiate polymerization of the monomer wherein the illuminating is according to a temporal and spatial illumination scheme, and wherein the amount of the initiator system and the temporal illumination scheme are chosen to produce a desired molecular weight of the polymer or oligomer. The microemulsion can further comprise an effective amount of an effective co-surfactant. The method can be used to produce polymers and copolymers.