Abstract: High integrity shallow source/drain junctions are formed employing cobalt silicide contacts. Embodiments include depositing a layer of cobalt on a substrate above intended source/drain regions, depositing a cap layer of titanium or titanium nitride on the cobalt, depositing a doped film on the cap layer, and performing silicidation, as by rapid thermal annealing, to form a low-resistivity cobalt silicide and to diffuse impurities from the doped film through the cobalt silicide into the substrate to form a junction extending into the substrate a constant depth below the cobalt silicide interface. The formation of source/drain junctions self-aligned to the cobalt silicide/silicon interface prevents junction leakage while allowing the formation of cobalt silicide contacts at optimum thickness, thereby facilitating reliable device scaling.

Abstract: An insulated trench isolation structure is formed in a semiconductor substrate omitting a barrier nitride polish stop layer while avoiding substrate damage, thereby simplifying trench formation and improving planarity. After trench fill, polishing is conducted to effect substantial planarization without exposing the substrate surface, thereby avoiding substrate damage. Etching is then conducted to expose the substrate surface. The omission of the barrier nitride polish stop avoids generation of a topographical step at the substrate/trench fill interface, thereby enhancing the accuracy of subsequent photolithographic techniques in forming features with minimal dimensions.

Abstract: An insulated trench isolation structure with large and small trenches of differing widths is formed in a semiconductor substrate using a simplified reverse source/drain planarization mask. Embodiments include forming trenches and refilling them with an insulating material which also covers the substrate surface, polishing to remove an upper portion of the insulating material and to planarize the insulating material above the small trenches, depositing a second, thin layer of insulating material filling seams in the insulating material above the small trenches, masking the insulating material above the large trenches, isotropically etching, and polishing to planarize the insulating material. Since the insulating material is partially planarized and the seams over the small trenches are filled, etching can be carried out after the formation of a relatively simple planarization mask over only the large trenches, and not the small trenches.

Abstract: A shallow trench isolation structure is formed which enables the growth of a high quality gate oxide at the trench edges and protects the field oxide from gouging during post-gate processing, such as during the local interconnect etch, thereby allowing the formation of high-quality implanted junctions. Embodiments include forming a photoresist mask directly on a pad oxide layer which, in turn, is formed on a main surface of a semiconductor substrate or an epitaxial layer on a semiconductor substrate. After masking, the substrate is etched to form a trench, an oxide liner is grown in the trench surface, and a polish stop layer is deposited in the trench on the oxide liner and on the pad oxide layer. The polish stop layer is then masked to the trench edges, and the polish stop in the trench is anisotropically etched, to remove the polish stop at the bottom of the trenches leaving a portion overlying the side surfaces and edges of the trench on the oxide liner.

Abstract: Via void formation is substantially reduced or eliminated between the steps of depositing a barrier layer on a HSQ gap fill layer, and filling a through-hole with a conductive material deposited on the barrier layer, by performing a low-temperature baking following the deposition of the barrier layer. In particular, a high-temperature, low-pressure degas operation is performed immediately preceding, and in-situ with, the tungsten plug deposition that fills the through-hole to form a via. The low-pressure baking is performed at a high temperature and sufficiently low pressure that is less than the vapor pressure of imparities contained in the HSQ. Hence, any exposed portions of the HSQ gap fill layer that are not covered by the barrier layer (e.g., the titanium nitride (TiN) liner) will be outgassed during the low-pressure baking to minimize the possibility of HSQ outgas during tungsten deposition.

Abstract: Accurate photolighographic processing is achieved employing a stepper global alignment structure enabling formation thereon of a substantially transparent layer having a substantially planar upper surface. Embodiments include a set of global alignment marks comprising spaced apart trenches, each trench segmented into a plurality of narrow trenches spaced apart by uprights and forming a dummy topographical area of narrow trenches surrounding the set of alignment marks. The segmented trenches and the dummy topographical area effectively provide a substantially uniform topography enabling deposition of a transparent layer without steps and effective local planarization. Since the upper surface of the transparent layer is substantially planar, layers of material deposited on the transparent layer during subsequent processing also have a substantially planar upper surface, thereby enabling transmission of the signal produced by the alignment marks to the stepper with minimal distortion.

Abstract: Sharply-defined dopant profiles in the transistor channel region of ultra high density semiconductor devices are maintained by selective transistor channel implants to reduce exposure to heat cycling, thereby reducing dopant diffusion. Embodiments include forming isolation regions on a semiconductor substrate, forming a relatively thick first gate dielectric layer, then performing transistor channel implantations. The first gate dielectric layer is then masked and etched, and a second, thinner gate dielectric layer is formed. The transistor channel implants are not affected by the temperature cycle of the first gate dielectric layer formation, thereby enabling dual gate dielectric formation without adversely affecting the electrical characteristics of the finished device.

Abstract: A shallow trench isolation structure is formed which enables the growth of a high quality gate oxide at the trench edges. Embodiments include forming a photoresist mask directly on a pad oxide layer which, in turn, is formed on a main surface of a semiconductor substrate or an epitaxial layer on a semiconductor substrate. After masking, the substrate is etched to form a trench, an oxide liner is grown in the trench surface, and a polish stop layer is deposited over the oxide liner and the pad oxide layer. The polish stop layer is then masked to the trench edges, and the polish stop in the trench etched away. The trench is then filled with an insulating material, the insulating material is planarized, and the polish stop is removed by etching. Thus, the oxide liner is allowed to grow on the trench edges without the restraint of a polish stop, resulting in a thick, rounded oxide on the trench edges. Additionally, no polish stop layer remains in the trench to cause unwanted electrical effects.

Abstract: An insulated trench isolation structure is formed in a semiconductor substrate omitting a barrier nitride polish stop layer, thereby simplifying the formation of the trench isolating structure, and enabling the substrate to be polished substantially flush with the trench fill. The planar trench fill-substrate interface avoids additional topography, thereby facilitating application of, and enhancing the accuracy of, photolithographic techniques in forming features with minimal dimensions.

Abstract: An insulated trench isolation structure is formed in a semiconductor substrate using a thin amorphous silicon or polysilicon polish stop layer by adding a reflectance compensation layer on the polish stop layer. As a result, the topological step between the main surface of the substrate and the uppermost surface of the trench fill is reduced, thereby facilitating the application and enhancing the accuracy of photolithographic techniques in forming features with minimal dimensions.

Abstract: A method and apparatus is provided for simplifying the manufacture of an interlayer dielectric where local interconnects are utilized. The invention utilizes a separate LI stack and first contact stack deposition and etch. In the first step, a layer of oxide etch stop and a layer of TEOS oxide are deposited to form a first LI stack. This stack is then contact etched, filled, and polished. A first contact stack is then formed by deposition of a doped silane oxide layer that is contact etched, filled, and polished. The method produces an ILD with a first layer of oxide etch stop, a second layer of undoped TEOS oxide, and a final layer of doped silane oxide.