Patent application number | Description | Published |
20130252142 | IMAGING DEVICES, METHODS OF FORMING SAME, AND METHODS OF FORMING SEMICONDUCTOR DEVICE STRUCTURES - 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. | 09-26-2013 |
20130302981 | Semiconductor Constructions And Methods Of Forming Patterns - 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. | 11-14-2013 |
20140127909 | Methods Of Forming A Pattern On A Substrate - A method of forming a pattern on a substrate includes forming longitudinally elongated first lines and first sidewall spacers longitudinally along opposite sides of the first lines elevationally over an underlying substrate. Longitudinally elongated second lines and second sidewall spacers are formed longitudinally along opposite sides of the second lines. The second lines and the second sidewall spacers cross elevationally over the first lines and the first sidewall spacers. The second sidewall spacers are removed from crossing over the first lines. The first and second lines are removed in forming a pattern comprising portions of the first and second sidewall spacers over the underlying substrate. Other methods are disclosed. | 05-08-2014 |
20140145311 | METHODS OF FORMING FEATURES IN SEMICONDUCTOR DEVICE STRUCTURES - Methods of forming features are disclosed. One method comprises forming a resist over a pool of acidic or basic material on a substrate structure, selectively exposing the resist to an energy source to form exposed resist portions and non-exposed resist portions, and diffusing acid or base of the acidic or basic material from the pool into proximal portions of the resist. Another method comprises forming a plurality of recesses in a substrate structure. The plurality of recesses are filled with a pool material comprising acid or base. A resist is formed over the pool material and the substrate structure and acid or base is diffused into adjacent portions of the resist. The resist is patterned to form openings in the resist. The openings comprise wider portions distal to the substrate structure and narrower portions proximal to the substrate structure. Additional methods and semiconductor device structures including the features are disclosed. | 05-29-2014 |
20140299971 | METHODS OF FORMING A REVERSED PATTERN IN A SUBSTRATE, AND RELATED SEMICONDUCTOR DEVICE STRUCTURES - 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. | 10-09-2014 |
20140353803 | SEMICONDUCTOR DEVICE STRUCTURES - Methods of forming features are disclosed. One method comprises forming a resist over a pool of acidic or basic material on a substrate structure, selectively exposing the resist to an energy source to form exposed resist portions and non-exposed resist portions, and diffusing acid or base of the acidic or basic material from the pool into proximal portions of the resist. Another method comprises forming a plurality of recesses in a substrate structure. The plurality of recesses are filled with a pool material comprising acid or base. A resist is formed over the pool material and the substrate structure and acid or base is diffused into adjacent portions of the resist. The resist is patterned to form openings in the resist. The openings comprise wider portions distal to the substrate structure and narrower portions proximal to the substrate structure. Additional methods and semiconductor device structures including the features are disclosed. | 12-04-2014 |
20140370684 | METHODS FOR FORMING SUB-RESOLUTION FEATURES IN SEMICONDUCTOR DEVICES - Methods of forming semiconductor devices and features in semiconductor device structures include conducting an anti-spacer process to remove portions of a first mask material to form first openings extending in a first direction. Another anti-spacer process is conducted to remove portions of the first mask material to form second openings extending in a second direction at an angle to the first direction. Portions of the second mask material underlying the first mask material at intersections of the first openings and second openings are removed to form holes in the second mask material and to expose a substrate underlying the second mask material. | 12-18-2014 |
20150015860 | Reticles, And Methods Of Mitigating Asymmetric Lens Heating In Photolithography - A method of mitigating asymmetric lens heating in photolithographically patterning a photo-imageable 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-imageable 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-imageable material. Other implementations are contemplated, including reticles which may be independent of method of use or fabrication. | 01-15-2015 |