Patent application number | Description | Published |
20080203485 | STRAINED METAL GATE STRUCTURE FOR CMOS DEVICES WITH IMPROVED CHANNEL MOBILITY AND METHODS OF FORMING THE SAME - A gate structure for complementary metal oxide semiconductor (CMOS) devices includes a first gate stack having a first gate dielectric layer formed over a substrate, and a first metal layer formed over the first gate dielectric layer. A second gate stack includes a second gate dielectric layer formed over the substrate and a second metal layer formed over the second gate dielectric layer. The first metal layer is formed in manner so as to impart a tensile stress on the substrate, and the second metal layer is formed in a manner so as to impart a compressive stress on the substrate. | 08-28-2008 |
20080272437 | Threshold Adjustment for High-K Gate Dielectric CMOS - A CMOS structure is disclosed in which a first type FET has an extremely thin oxide liner. This thin liner is capable of preventing oxygen from reaching the high-k dielectric gate insulator of the first type FET. A second type FET device of the CMOS structure has a thicker oxide liner. As a result, an oxygen exposure is capable to shift the threshold voltage of the second type of FET, without affecting the threshold value of the first type FET. The disclosure also teaches methods for producing the CMOS structure in which differing type of FET devices have differing thickness liners, and the threshold values of the differing type of FET devices is set independently from one another. | 11-06-2008 |
20080277726 | Devices with Metal Gate, High-k Dielectric, and Butted Electrodes - FET device structures are disclosed with the PFET and NFET devices having high-k dielectric gate insulators and metal containing gates. The metal layers of the gates in both the NFET and PFET devices have been fabricated from a single common metal layer. As a consequence of using a single layer of metal for the gates of both type of devices, the terminal electrodes of NFETs and PFETs can be butted to each other in direct physical contact. The FET device structures further contain stressed device channels, and gates with effective workfunctions of n | 11-13-2008 |
20090039434 | Simple Low Power Circuit Structure with Metal Gate and High-k Dielectric - FET device structures are disclosed with the PFET and NFET devices having high-k dielectric gate insulators and metal containing gates. The metal layers of the gates in both the NFET and PFET devices have been fabricated from a single common metal layer. Due to the single common metal, device fabrication is simplified, requiring a reduced number of masks. Also, as a further consequence of using a single layer of metal for the gates of both type of devices, the terminal electrodes of NFETs and PFETs can be butted to each other in direct physical contact. Device thresholds are adjusted by the choice of the common metal material and oxygen exposure of the high-k dielectric. Threshold values are aimed for low power consumption device operation. | 02-12-2009 |
20090039435 | Low Power Circuit Structure with Metal Gate and High-k Dielectric - FET device structures are disclosed with the PFET and NFET devices having high-k dielectric gate insulators, metal containing gates, and threshold adjusting cap layers. The NFET gate stack and the PFET gate stack each has a portion which is identical in the NFET device and in the PFET device. This identical portion contains at least a gate metal layer and a cap layer. Due to the identical portion, device fabrication is simplified, requiring a reduced number of masks. Furthermore, as a consequence of using a single layer of metal for the gates of both type of devices, the terminal electrodes of NFETs and PFETs can be butted with each other in direct physical contact. Device thresholds are further adjusted by oxygen exposure of the high-k dielectric. Threshold values are aimed for low power consumption device operation. | 02-12-2009 |
20090039436 | High Performance Metal Gate CMOS with High-K Gate Dielectric - A CMOS structure is disclosed in which both type of FET devices have gate insulators containing high-k dielectrics, and gates containing metals. The threshold of the two type of devices are adjusted in separate manners. One type of device has its threshold set by exposing the high-k dielectric to oxygen. During the oxygen exposure the other type of device is covered by a stressing dielectric layer, which layer also prevents oxygen penetration to its high-k gate dielectric. The high performance of the CMOS structure is further enhanced by adjusting the effective workfunctions of the gates to near band-edge values both NFET and PFET devices. | 02-12-2009 |
20090212369 | Gate Effective-Workfunction Modification for CMOS - CMOS circuit structures are disclosed with the PFET and NFET devices having high-k dielectric layers consisting of the same gate insulator material, and metal gate layers consisting of the same gate metal material. The PFET device has a “p” interface control layer which is capable of shifting the effective-workfunction of the gate in the p-direction. In a representative embodiment of the invention the “p” interface control layer is aluminum oxide. The NFET device may have an “n” interface control layer. The materials of the “p” and “n” interface control layers are differing materials. The “p” and “n” interface control layers are positioned to the opposite sides of their corresponding high-k dielectric layers. Methods for fabricating the CMOS circuit structures with the oppositely positioned “p” and “n” interface control layers are also disclosed. | 08-27-2009 |
20090283838 | Fabrication of self-aligned CMOS structure - A method for fabricating a CMOS structure is disclosed. The method includes the blanket disposition of a high-k gate insulator layer in an NFET device and in a PFET device, and the implementation of a gate metal layer over the NFET device. This is followed by a blanket disposition of an Al layer over both the NFET device and the PFET device. The method further involves a blanket disposition of a shared gate metal layer over the Al layer. When the PFET device is exposed to a thermal annealing, the high-k dielectric oxidizes the Al layer, thereby turning the Al layer into a PFET interfacial control layer, while in the NFET device the Al becomes a region of the metal gate. | 11-19-2009 |
20090291553 | Threshold Adjustment for High-K Gate Dielectric CMOS - A CMOS structure is disclosed in which a first type FET has an extremely thin oxide liner. This thin liner is capable of preventing oxygen from reaching the high-k dielectric gate insulator of the first type FET. A second type FET device of the CMOS structure has a thicker oxide liner. As a result, an oxygen exposure is capable to shift the threshold voltage of the second type of FET, without affecting the threshold value of the first type FET. The disclosure also teaches methods for producing the CMOS structure in which differing type of FET devices have differing thickness liners, and the threshold values of the differing type of FET devices is set independently from one another. | 11-26-2009 |
20110001195 | Fabrication of self-aligned CMOS structure - A method for fabricating a CMOS structure is disclosed. The method includes the blanket disposition of a high-k gate insulator layer in an NFET device and in a PFET device, and the implementation of a gate metal layer over the NFET device. This is followed by a blanket disposition of an Al layer over both the NFET device and the PFET device. The method further involves a blanket disposition of a shared gate metal layer over the Al layer. When the PFET device is exposed to a thermal annealing, the high-k dielectric oxidizes the Al layer, thereby turning the Al layer into a PFET interfacial control layer, while in the NFET device the Al becomes a region of the metal gate. | 01-06-2011 |
20110121401 | Gate Effective-Workfunction Modification for CMOS - CMOS circuit structures are disclosed with the PFET and NFET devices having high-k dielectric layers consisting of the same gate insulator material, and metal gate layers consisting of the same gate metal material. The PFET device has a “p” interface control layer which is capable of shifting the effective-workfunction of the gate in the p-direction. In a representative embodiment of the invention the “p” interface control layer is aluminum oxide. The NFET device may have an “n” interface control layer. The materials of the “p” and “n” interface control layers are differing materials. The “p” and “n” interface control layers are positioned to the opposite sides of their corresponding high-k dielectric layers. Methods for fabricating the CMOS circuit structures with the oppositely positioned “p” and “n” interface control layers are also disclosed. | 05-26-2011 |