Patent application number | Description | Published |
20090008719 | METAL GATE CMOS WITH AT LEAST A SINGLE GATE METAL AND DUAL GATE DIELECTRICS - A complementary metal oxide semiconductor (CMOS) structure including at least one nFET and at least one pFET located on a surface of a semiconductor substrate is provided. In accordance with the present invention, the nFET and the pFET both include at least a single gate metal and the nFET gate stack is engineered to have a gate dielectric stack having no net negative charge and the pFET gate stack is engineered to have a gate dielectric stack having no net positive charge. In particularly, the present invention provides a CMOS structure in which the nFET gate stack is engineered to include a band edge workfunction and the pFET gate stack is engineered to have a ¼ gap workfunction. In one embodiment of the present invention, the first gate dielectric stack includes a first high k dielectric and an alkaline earth metal-containing layer or a rare earth metal-containing layer, while the second high k gate dielectric stack comprises a second high k dielectric. | 01-08-2009 |
20090008720 | METAL GATE CMOS WITH AT LEAST A SINGLE GATE METAL AND DUAL GATE DIELECTRICS - A complementary metal oxide semiconductor (CMOS) structure including at least one nFET and at least one pFET located on a surface of a semiconductor substrate is provided. In accordance with the present invention, the nFET and the pFET both include at least a single gate metal and the nFET gate stack is engineered to have a gate dielectric stack having no net negative charge and the pFET gate stack is engineered to have a gate dielectric stack having no net positive charge. In particularly, the present invention provides a CMOS structure in which the nFET gate stack is engineered to include a band edge workfunction and the pFET gate stack is engineered to have a ¼ gap workfunction. In one embodiment of the present invention, the first gate dielectric stack includes a first high k dielectric and an alkaline earth metal-containing layer or a rare earth metal-containing layer, while the second high k gate dielectric stack comprises a second high k dielectric. | 01-08-2009 |
20090011552 | METAL GATE CMOS WITH AT LEAST A SINGLE GATE METAL AND DUAL GATE DIELECTRICS - A complementary metal oxide semiconductor (CMOS) structure including at least one nFET and at least one pFET located on a surface of a semiconductor substrate is provided. In accordance with the present invention, the nFET and the pFET both include at least a single gate metal and the nFET gate stack is engineered to have a gate dielectric stack having no net negative charge and the pFET gate stack is engineered to have a gate dielectric stack having no net positive charge. In particularly, the present invention provides a CMOS structure in which the nFET gate stack is engineered to include a band edge workfunction and the pFET gate stack is engineered to have a ¼ gap workfunction. In one embodiment of the present invention, the first gate dielectric stack includes a first high k dielectric and an alkaline earth metal-containing layer or a rare earth metal-containing layer, while the second high k gate dielectric stack comprises a second high k dielectric. | 01-08-2009 |
20090302399 | Using Metal/Metal Nitride Bilayers as Gate Electrodes in Self-Aligned Aggressively Scaled CMOS Devices - The present invention is directed to CMOS structures that include at least one nMOS device located on one region of a semiconductor substrate; and at least one pMOS device located on another region of the semiconductor substrate. In accordance with the present invention, the at least one nMOS device includes a gate stack comprising a gate dielectric, a low workfunction elemental metal having a workfunction of less than 4.2 eV, an in-situ metallic capping layer, and a polysilicon encapsulation layer and the at least one pMOS includes a gate stack comprising a gate dielectric, a high workfunction elemental metal having a workfunction of greater than 4.9 eV, a metallic capping layer, and a polysilicon encapsulation layer. The present invention also provides methods of fabricating such a CMOS structure. | 12-10-2009 |
20100041221 | HIGH PERFORMANCE CMOS CIRCUITS, AND METHODS FOR FABRICATING SAME - The present invention relates to complementary metal-oxide-semiconductor (CMOS) circuits that each contains at least a first and a second gate stacks. The first gate stack is located over a first device region (e.g., an n-FET device region) in a semiconductor substrate and comprises at least, from bottom to top, a gate dielectric layer, a metallic gate conductor, and a silicon-containing gate conductor. The second gate stack is located over a second device region (e.g., a p-FET device region) in the semiconductor substrate and comprises at least, from bottom to top, a gate dielectric layer and a silicon-containing gate conductor. The first and second gate stacks can be formed over the semiconductor substrate in an integrated manner by various methods of the present invention. | 02-18-2010 |
20100044805 | METAL GATES WITH LOW CHARGE TRAPPING AND ENHANCED DIELECTRIC RELIABILITY CHARACTERISTICS FOR HIGH-k GATE DIELECTRIC STACKS - A multilayered gate stack having improved reliability (i.e., low charge trapping and gate leakage degradation) is provided. The inventive multilayered gate stack includes, from bottom to top, a metal nitrogen-containing layer located on a surface of a high-k gate dielectric and Si-containing conductor located directly on a surface of the metal nitrogen-containing layer. The improved reliability is achieved by utilizing a metal nitrogen-containing layer having a compositional ratio of metal to nitrogen of less than 1.1. The inventive gate stack can be useful as an element of a complementary metal oxide semiconductor (CMOS). The present invention also provides a method of fabricating such a gate stack in which the process conditions of a sputtering process are varied to control the ratio of metal and nitrogen within the sputter deposited layer. | 02-25-2010 |
20130212414 | REDUCING PERFORMANCE DEGRADATION IN BACKUP SEMICONDUCTOR CHIPS - A system has at least a first circuit portion and a second circuit portion. The first circuit portion is operated at normal AC frequency. The second circuit portion is operated in a back-up mode at low AC frequency, such that the second circuit portion can rapidly come-online but has limited temperature bias instability degradation. The second circuit portion can then be brought on-line and operated at the normal AC frequency. A system including first and second circuit portions and a control unit, as well as a computer program product, are also provided. | 08-15-2013 |
20140042546 | STRUCTURE AND METHOD TO FORM INPUT/OUTPUT DEVICES - A limited number of cycles of atomic layer deposition (ALD) of Hi-K material followed by deposition of an interlayer dielectric and application of further Hi-K material and optional but preferred annealing provides increased Hi-K material content and increased breakdown voltage for input/output (I/O) transistors compared with logic transistors formed on the same chip or wafer while providing scalability of the inversion layer of the I/O and logic transistors without significantly compromising performance or bias temperature instability (BTI) parameters. | 02-13-2014 |
20140159162 | BULK FINFET WITH SUPER STEEP RETROGRADE WELL - A method for forming a fin transistor in a bulk substrate includes forming a super steep retrograde well (SSRW) on a bulk substrate. The well includes a doped portion of a first conductivity type dopant formed below an undoped layer. A fin material is grown over the undoped layer. A fin structure is formed from the fin material, and the fin material is undoped or doped. Source and drain regions are provided adjacent to the fin structure to form a fin field effect transistor. | 06-12-2014 |
20140159163 | BULK FINFET WITH SUPER STEEP RETROGRADE WELL - A method for forming a fin transistor in a bulk substrate includes forming a super steep retrograde well (SSRW) on a bulk substrate. The well includes a doped portion of a first conductivity type dopant formed below an undoped layer. A fin material is grown over the undoped layer. A fin structure is formed from the fin material, and the fin material is undoped or doped. Source and drain regions are provided adjacent to the fin structure to form a fin field effect transistor. | 06-12-2014 |
20140244212 | Monitoring Aging of Silicon in an Integrated Circuit Device - A mechanism is provided for determining a modeled age of a mufti-core processor. For each core in a set of cores in the multi-core processor, a determination is made of a temperature, a voltage, and a frequency at regular intervals for a set of degradations and a set of voltage domains, thereby forming the modeled age of the multi-core processor. A determination is made as to whether the modeled age of the multi-core processor is greater than an end-of-life value. Responsive to the modeled age of the multi-core processor being greater than an end-of-life value, an indication is sent that the multi-core processor requires replacement. | 08-28-2014 |
20140252503 | MULTI-PLASMA NITRIDATION PROCESS FOR A GATE DIELECTRIC - A gate dielectric can be formed by depositing a first silicon oxide material by a first atomic layer deposition process. The thickness of the first silicon oxide material is selected to correspond to at least 10 deposition cycles of the first atomic layer deposition process. The first silicon oxide material is converted into a first silicon oxynitride material by a first plasma nitridation process. A second silicon oxide material is subsequently deposited by a second atomic layer deposition process. The second silicon oxide material is converted into a second silicon oxynitride material by a second plasma nitridation process. Multiple repetitions of the atomic layer deposition process and the plasma nitridation process provides a silicon oxynitride material having a ratio of nitrogen atoms to oxygen atoms greater than 1/3, which can be advantageously employed to reduce the leakage current through a gate dielectric. | 09-11-2014 |
20140308821 | HYDROXYL GROUP TERMINATION FOR NUCLEATION OF A DIELECTRIC METALLIC OXIDE - A surface of a semiconductor-containing dielectric material/oxynitride/nitride is treated with a basic solution in order to provide hydroxyl group termination of the surface. A dielectric metal oxide is subsequently deposited by atomic layer deposition. The hydroxyl group termination provides a uniform surface condition that facilitates nucleation and deposition of the dielectric metal oxide, and reduces interfacial defects between the oxide and the dielectric metal oxide. Further, treatment with the basic solution removes more oxide from a surface of a silicon germanium alloy with a greater atomic concentration of germanium, thereby reducing a differential in the total thickness of the combination of the oxide and the dielectric metal oxide across surfaces with different germanium concentrations. | 10-16-2014 |
20150021698 | Intrinsic Channel Planar Field Effect Transistors Having Multiple Threshold Voltages - Intrinsic channels one or more intrinsic semiconductor materials are provided in a semiconductor substrate. A high dielectric constant (high-k) gate dielectric layer is formed on the intrinsic channels. A patterned diffusion barrier metallic nitride layer is formed. A threshold voltage adjustment oxide layer is formed on the physically exposed portions of the high-k gate dielectric layer and the diffusion barrier metallic nitride layer. An anneal is performed to drive in the material of the threshold voltage adjustment oxide layer to the interface between the intrinsic channel(s) and the high-k gate dielectric layer, resulting in formation of threshold voltage adjustment oxide portions. At least one work function material layer is formed, and is patterned with the high-k gate dielectric layer and the threshold voltage adjustment oxide portions to form multiple types of gate stacks. | 01-22-2015 |
Patent application number | Description | Published |
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 |
20090298245 | 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. | 12-03-2009 |
20120074533 | Structures And Techniques For Atomic Layer Deposition - In one exemplary embodiment, a method includes: forming at least one first monolayer of first material on a surface of a substrate by performing a first plurality of cycles of atomic layer deposition; thereafter, annealing the formed at least one first monolayer of first material under a first inert atmosphere at a first temperature between about 650° C. and about 900° C.; thereafter, forming at least one second monolayer of second material by performing a second plurality of cycles of atomic layer deposition, where the formed at least one second monolayer of second material at least partially overlies the annealed at least one first monolayer of first material; and thereafter, annealing the formed at least one second monolayer of second material under a second inert atmosphere at a second temperature between about 650° C. and about 900° C. | 03-29-2012 |