| Patent application number | Description | Published |
|---|
| 20100320545 | PLANAR AND NON-PLANAR CMOS DEVICES WITH MULTIPLE TUNED THRESHOLD VOLTAGES - A semiconductor structure is provided that includes a first device region including a first threshold voltage adjusting layer located atop a semiconductor substrate, a gate dielectric located atop the first threshold voltage adjusting layer, and a gate conductor located atop the gate dielectric. The structure further includes a second device region including a gate dielectric located atop the semiconductor substrate, and a gate conductor located atop the gate dielectric; and a third device region including a gate dielectric located atop the semiconductor substrate, a second threshold voltage adjusting layer located atop the gate dielectric, and a gate conductor located atop the second threshold voltage adjusting layer. In the inventive structure the first threshold voltage adjusting layer includes one of an nFET threshold voltage adjusting material or a pFET threshold voltage adjusting material and the second threshold voltage adjusting layer is the other of the nFET threshold voltage adjusting material or the pFET threshold voltage adjusting material. | 12-23-2010 |
| 20110081754 | METHODS FOR OBTAINING GATE STACKS WITH TUNABLE THRESHOLD VOLTAGE AND SCALING - Methods of forming complementary metal oxide semiconductor (CMOS) structures with tunable threshold voltages are provided. The methods disclose a technique of obtaining selective placement of threshold voltage adjusting materials on a semiconductor substrate by using a block mask prior to deposition of the threshold voltage adjusting materials. The block mask is subsequently removed to obtain a patterned threshold voltage adjusting material on the semiconductor substrate. The methods are material independent and can be used in sequence for both nFET threshold voltage adjusting materials and pFET threshold voltage adjusting materials. | 04-07-2011 |
| 20110081765 | METHOD TO IMPROVE WET ETCH BUDGET IN FEOL INTEGRATION - A method of forming a semiconductor device is provided where in one embodiment an STI fill is recessed below the pad nitride and pad oxide layers, to a level substantially coplanar with the top surface of the substrate. A thin (having a thickness in the range of about 10 Å-100 Å) wet etch resistant layer is formed in contact with and completely covering at least the top surface of the recessed STI fill material. The thin wet etch resistant layer is more resistant to a wet etch process than at least the pad oxide layer. The thin wet etch resistant layer may be a refractory dielectric material, or a dielectric such as HfO | 04-07-2011 |
| 20110108921 | SINGLE METAL GATE CMOS INTEGRATION BY INTERMIXING POLARITY SPECIFIC CAPPING LAYERS - A method for forming a complementary metal oxide semiconductor device includes forming a first capping layer on a dielectric layer, blocking portions in the capping layer in regions where the capping layer is to be preserved using a block mask. Exposed portions of the first capping layer are intermixed with the dielectric layer to form a first intermixed layer. The block mask is removed. The first capping layer and the first intermixed layer are etched such that the first capping layer is removed to re-expose the dielectric layer in regions without removing the first intermixed layer. | 05-12-2011 |
| 20110115026 | CONTROL OF THRESHOLD VOLTAGES IN HIGH-K METAL GATE STACK AND STRUCTURES FOR CMOS DEVICES - A high-k metal gate stack and structures for CMOS devices and a method for forming the devices. The gate stack includes a germanium (Ge) material layer formed on the semiconductor substrate, a diffusion barrier layer formed on the Ge material layer, a high-k dielectric having a high dielectric constant greater than approximately 3.9 formed over the diffusion barrier layer, and a conductive electrode layer formed above the high-k dielectric layer. | 05-19-2011 |
| 20110115027 | STRUCTURE AND METHOD TO OBTAIN EOT SCALED DIELECTRIC STACKS - Equivalent oxide thickness (EOT) scaled high k/metal gate stacks are provided in which the capacitance bottleneck of the interfacial layer is substantially eliminated, with minimal compromise on the mobility of carriers in the channel of the device. In one embodiment, the aforementioned EOT scaled high k/metal gate stacks are achieved by increasing the dielectric constant of the interfacial layer to a value that is greater than the originally formed interfacial layer, i.e., the interfacial layer prior to diffusion of a high k material dopant element therein. In another embodiment, the aforementioned scaled high k/metal gate stacks are achieved by eliminating the interfacial layer from the structure. In yet another embodiment, the aforementioned high k/metal gate stacks are achieved by both increasing the dielectric constant of the interfacial layer and reducing/eliminating the interfacial layer. | 05-19-2011 |
| 20110212548 | METHOD FOR SEMICONDUCTOR GATE HARDMASK REMOVAL AND DECOUPLING OF IMPLANTS - A method is provided for fabricating a semiconductor device having implanted source/drain regions and a gate region, the gate region having been masked by the gate hardmask during source/drain implantation, the gate region having a polysilicon gate layered on a metal layered on a high-K dielectric layer. The gate region and the source/drain regions may be covered with a self planarizing spin on film. The film may be blanket etched back to uncover the gate hardmask while maintaining an etched back self planarizing spin on film on the implanted source/drain regions. The gate hardmask may be etched back while the etched back film remains in place to protect the implanted source/drain regions. The gate region may be low energy implanted to lower sheet resistance of the polysilicon layer. The etched back film may be then removed. | 09-01-2011 |
| 20110260257 | High Performance Non-Planar Semiconductor Devices with Metal Filled Inter-Fin Gaps - A non-planar semiconductor transistor device includes a substrate layer. Conductive channels extend between corresponding source and drain electrodes. A gate stack extending in a direction perpendicular to the conductive channels crosses over the plurality of conductive channels. The gate stack includes a dielectric layer running along the substrate and the plurality of conductive channels and arranged with a substantially uniform layer thickness, a work-function electrode layer covers the dielectric layer and is arranged with a substantially uniform layer thickness, and a metal layer, distinct from the work-function electrode layer, covers the work-function electrode layer and is arranged with a substantially uniform height with respect to the substrate such that the metal layer fills a gap between proximate conductive channels of the plurality of conductive channels. | 10-27-2011 |
