| Patent application number | Description | Published |
|---|
| 20090004799 | METHOD OF FORMING A SEMICONDUCTOR STRUCTURE COMPRISING A FORMATION OF AT LEAST ONE SIDEWALL SPACER STRUCTURE - According to an illustrative example, a method of forming a semiconductor structure comprises providing a semiconductor substrate comprising a first feature and a second feature. A material layer is formed over the first feature and the second feature. A mask is formed over the first feature. At least one etch process adapted to form a sidewall spacer structure adjacent the second feature from a portion of the material layer is performed. The mask protects a portion of the material layer over the first feature from being affected by the at least one etch process. An ion implantation process is performed. The mask remains over the first feature during the ion implantation process. | 01-01-2009 |
| 20090142900 | METHOD FOR CREATING TENSILE STRAIN BY SELECTIVELY APPLYING STRESS MEMORIZATION TECHNIQUES TO NMOS TRANSISTORS - By selectively applying a stress memorization technique to N-channel transistors, a significant improvement of transistor performance may be achieved. High selectivity in applying the stress memorization approach may be accomplished by substantially maintaining the crystalline state of the P-channel transistors while annealing the N-channel transistors in the presence of an appropriate material layer which may not to be patterned prior to the anneal process, thereby avoiding additional lithography and masking steps. | 06-04-2009 |
| 20090273036 | METHOD FOR REDUCING DEFECTS OF GATE OF CMOS DEVICES DURING CLEANING PROCESSES BY MODIFYING A PARASITIC PN JUNCTION - By incorporating nitrogen into the P-doped regions and N-doped regions of the gate electrode material prior to patterning the gate electrode structure, yield losses due to reactive wet chemical cleaning processes may be significantly reduced. | 11-05-2009 |
| 20110024846 | LEAKAGE CONTROL IN FIELD EFFECT TRANSISTORS BASED ON AN IMPLANTATION SPECIES INTRODUCED LOCALLY AT THE STI EDGE - In a static memory cell, the failure rate upon forming contact elements connecting an active region with a gate electrode structure formed above an isolation region may be significantly reduced by incorporating an implantation species at a tip portion of the active region through a sidewall of the isolation trench prior to filling the same with an insulating material. The implantation species may represent a P-type dopant species and/or an inert species for significantly modifying the material characteristics at the tip portion of the active region. | 02-03-2011 |
| 20110101469 | STRAIN ENHANCEMENT IN TRANSISTORS COMPRISING AN EMBEDDED STRAIN-INDUCING SEMICONDUCTOR ALLOY BY CORNER ROUNDING AT THE TOP OF THE GATE ELECTRODE - In MOS transistor elements, a strain-inducing semiconductor alloy may be embedded in the active region with a reduced offset from the channel region by applying a spacer structure of reduced width. In order to reduce the probability of creating semiconductor residues at the top area of the gate electrode structure, a certain degree of corner rounding of the semiconductor material may be introduced, which may be accomplished by ion implantation prior to epitaxially growing the strain-inducing semiconductor material. This concept may be advantageously combined with the provision of sophisticated high-k metal gate electrodes that are provided in an early manufacturing stage. | 05-05-2011 |
| 20110156172 | ENHANCING DEPOSITION UNIFORMITY OF A CHANNEL SEMICONDUCTOR ALLOY BY FORMING A RECESS PRIOR TO THE WELL IMPLANTATION - When forming sophisticated gate electrode structures requiring a threshold adjusting semiconductor alloy for one type of transistor, a recess is formed in the corresponding active region, thereby providing superior process uniformity during the deposition of the semiconductor material. Moreover, the well dopant species is implanted after the recessing, thereby avoiding undue dopant loss. Due to the recess, any exposed sidewall surface areas of the active region may be avoided during the selective epitaxial growth process, thereby significantly contributing to enhanced threshold stability of the resulting transistor including the high-k metal gate stack. | 06-30-2011 |
| 20110291163 | Reduction of Defect Rates in PFET Transistors Comprising a Si/Ge Semiconductor Material Formed by Epitaxial Growth - In sophisticated semiconductor devices, the defect rate that may typically be associated with the provision of a silicon/germanium material in the active region of P-channel transistors may be significantly decreased by incorporating a carbon species prior to or during the selective epitaxial growth of the silicon/germanium material. In some embodiments, the carbon species may be incorporated during the selective growth process, while in other cases an ion implantation process may be used. In this case, superior strain conditions may also be obtained in N-channel transistors. | 12-01-2011 |
| 20120001254 | Transistor With Embedded Si/Ge Material Having Reduced Offset and Superior Uniformity - In sophisticated semiconductor devices, a strain-inducing embedded semiconductor alloy may be provided on the basis of a crystallographically anisotropic etch process and a self-limiting deposition process, wherein transistors which may not require an embedded strain-inducing semiconductor alloy may remain non-masked, thereby providing superior uniformity with respect to overall transistor configuration. Consequently, superior strain conditions may be achieved in one type of transistor, while generally reduced variations in transistor characteristics may be obtained for any type of transistors. | 01-05-2012 |
