Abstract: A transistor structure and a method of forming same. The transistor structure includes: a semiconductor substrate having a gate-side surface; a gate disposed on the gate-side surface, the gate extending above the gate-side surface by a first height; a semiconductor extension disposed on the gate-side surface and extending above the gate-side surface by a second height larger than the first height, the semiconductor extension including a diffusion region having a diffusion surface located at the second height; and a diffusion contact element electrically coupled to the diffusion surface.

Abstract: Cross-shaped sub-resolution assist features may be utilized to print lithographic patterns in semiconductor fabrication processes. The crosses may be isolated structures or may be part of a grid arrangement. The main features, such as contacts, may be positioned on the mask so as to be intersected by the cross-shaped sub-resolution assist features. In some embodiments, the cross-shaped sub-resolution assist features may intersect the main feature at its center point in both the x and y directions.

Abstract: In one embodiment of the invention, contact patterning may be divided into two or more passes which may allow designers to control the gate height critical dimension relatively independent from the contact top critical dimension.

Abstract: In one embodiment, a mask for use in semiconductor processing comprises a first region formed from a first material that is primarily opaque, a second region formed from a second material that is primarily transmissive, and a third region in which at least a portion of the second material is removed to generate a phase shift in radiation applied to the mask.

Abstract: A nano-electrode or nano-wire may be etched centrally to form a gap between nano-electrode portions. The portions may ultimately constitute a single electron transistor. The source and drain formed from the electrode portions are self-aligned with one another. Using spacer technology, the gap between the electrodes may be made very small.

Abstract: A semiconductor wafer may be coated with an imageable anti-reflective coating. As a result, the coating may be removed using the same techniques used to remove overlying photoresists. This may overcome the difficulty of etching anti-reflective coatings using standard etches because of their poor selectivity to photoresist and the resulting propensity to cause integrated circuit defects arising from anti-reflective coating remnants.

Abstract: A nano-electrode or nano-wire may be etched centrally to form a gap between nano-electrode portions. The portions may ultimately constitute a single electron transistor. The source and drain formed from the electrode portions are self-aligned with one another. Using spacer technology, the gap between the electrodes may be made very small.

Abstract: A method for forming two trenches with tight end-to-end spacing in a dielectric layer begins with providing a substrate having a dielectric layer. A hard-mask layer is deposited on the dielectric layer and a first photoresist layer is deposited on the hard-mask layer. The first photoresist layer is patterned to form an extended trench in the first photoresist layer. The hard-mask layer is then etched using the first photoresist layer as a mask to form an extended trench in the hard-mask layer. Next, a second photoresist layer is deposited on the hard-mask layer and patterned to form a resist line that intersects the extended trench. The resist line divides the extended trench into two separate trenches. The dielectric layer is then etched using the hard-mask layer and the resist line as a mask, thereby forming two trenches in the dielectric layer with end-to-end separation that corresponds to the resist line width.

Abstract: A method to form transistor contacts begins with providing a transistor that includes a gate stack and first and second diffusion regions formed on a substrate, and a dielectric layer formed atop the gate stack and the diffusion regions. A first photolithography process forms first and second diffusion trench openings for the first and second diffusion regions. A sacrificial layer is then deposited into the first and second diffusion trench openings. Next, a second photolithography process forms a gate stack trench opening for the gate stack and a local interconnect trench opening coupling the gate stack trench opening to the first diffusion trench opening. The second photolithography process is carried out independent of the first photolithography process. The sacrificial layer is then removed and a metallization process is carried out to fill the first and second diffusion trench openings, the gate stack trench opening, and the local interconnect trench opening with a metal layer.

Abstract: A semiconductor wafer may be coated with an imageable anti-reflective coating. As a result, the coating may be removed using the same techniques used to remove overlying photoresists. This may overcome the difficulty of etching anti-reflective coatings using standard etches because of their poor selectivity to photoresist and the resulting propensity to cause integrated circuit defects arising from anti-reflective coating remnants.

Abstract: The present invention relates to the reduction of critical dimensions and the reduction of feature sizes in manufacturing integrated circuits. Specifically, the method controls photoresist flow rates to develop critical dimensions beyond the resolution limits of the photoresist material used, and the limits of lithographic tool sets. The resist material characteristics are modified by exposing the resist pattern to either electrons, photons, or ions. The exposure modifies the glass transition temperature, cross linking characteristics, decomposition temperature, or molecular weight of the resist material. The post-exposure resist is then easier to control during a subsequent reflow process to reduce the hole size or line size of the patterned resist.

Abstract: Cross-shaped sub-resolution assist features may be utilized to print lithographic patterns in semiconductor fabrication processes. The crosses may be isolated structures or may be part of a grid arrangement. The main features, such as contacts, may be positioned on the mask so as to be intersected by the cross-shaped sub-resolution assist features. In some embodiments, the cross-shaped sub-resolution assist features may intersect the main feature at its center point in both the x and y directions.

Abstract: Sub-resolution assist features for non-collinear features are described for use in photolithography. A photolithography mask with elongated features is synthesized. An end-to-end gap between two features if found for which the ends of the two features facing the gap are linearly offset from one another. A sub-resolution assist feature is applied to the end-to-end gap between the elongated features, and the synthesized photolithography mask is modified to include the sub-resolution assist feature.

Abstract: A semiconductor wafer may be coated with an imageable anti-reflective coating. As a result, the coating may be removed using the same techniques used to remove overlying photoresists. This may overcome the difficulty of etching anti-reflective coatings using standard etches because of their poor selectivity to photoresist and the resulting propensity to cause integrated circuit defects arising from anti-reflective coating remnants.

Abstract: Systems and techniques relating to the layout and use of sub-resolution assist features. In one implementation, a mask includes a first feature and a second feature separated from each other by a gap and a sub-resolution assist feature bridging the gap between the first feature and the second feature.

Abstract: The present invention relates to the reduction of critical dimensions and the reduction of feature sizes in manufacturing integrated circuits. Specifically, the method controls photoresist flow rates to develop critical dimensions beyond the resolution limits of the photoresist material used, and the limits of lithographic tool sets. The post exposure and developed resist pattern is exposed to a solvent prior to a bake or reflow process. Exposure to the solvent lowers the molecular weight of the resist material, modifying the resist material's reflow rate. The post-exposure resist is then easier to control during a subsequent reflow process to reduce the hole or line size of the patterned resist.

Abstract: The present invention relates to exposing a bond pad on a substrate. A bond pad is formed over a silicon substrate with the subsequent formation of a dielectric over the bond pad. A patterned resist is formed, and at least opening is processed to form a sloped sidewall profile. The sloped sidewall profile is subsequently etched and transferred to the dielectric layer, exposing the bond pad.

Abstract: The embodiments of the present invention include decomposing a pattern into dependent patterns. The dependent patterns may then be transferred to a semiconductor wafer surface and the pattern's features may be shrunk. The shrunk features may be transferred to the substrate. The multiple exposures and shrinks facilitate smaller feature dimensions.

Abstract: A nano-electrode or nano-wire may be etched centrally to form a gap between nano-electrode portions. The portions may ultimately constitute a single electron transistor. The source and drain formed from the electrode portions are self-aligned with one another. Using spacer technology, the gap between the electrodes may be made very small.

Abstract: Defective contact plug fills can be detected by applying an etching solution, which in some embodiments preferentially etches in the <111> direction. The etching solution is some embodiments may also produce a characteristic type of undercutting underneath the contact plug fill. Contact plug fills with defects in them have undercutting underneath as a result of the etchant exposure, while defective contact plug fills have no such undercutting. The contact plug fills that are now undercut by etching exposure are unable to dissipate surface charge or surface applied potential and can be detected using voltage contrast methods or conventional electrical testing techniques, for example.