Patent application number | Description | Published |
20080265330 | TECHNIQUE FOR ENHANCING TRANSISTOR PERFORMANCE BY TRANSISTOR SPECIFIC CONTACT DESIGN - By locally adapting the size and/or density of a contact structure, for instance, within individual transistors or in a more global manner, the overall performance of advanced semiconductor devices may be increased. Hence, the mutual interaction between the contact structure and local device characteristics may be taken into consideration. On the other hand, a high degree of compatibility with conventional process strategies may be maintained. | 10-30-2008 |
20080296692 | TECHNIQUE FOR STRAIN ENGINEERING IN SILICON-BASED TRANSISTORS BY USING IMPLANTATION TECHNIQUES FOR FORMING A STRAIN-INDUCING LAYER UNDER THE CHANNEL REGION - By incorporating a semiconductor species having the same valence and a different covalent radius compared to the base semiconductor material on the basis of an ion implantation process, a strain-inducing material may be positioned locally within a transistor at an appropriate manufacturing stage, thereby substantially not contributing to overall process complexity and also not affecting the further processing of the semiconductor device. Hence, a high degree of flexibility may be provided with respect to enhancing transistor performance in a highly local manner. | 12-04-2008 |
20090108336 | METHOD FOR ADJUSTING THE HEIGHT OF A GATE ELECTRODE IN A SEMICONDUCTOR DEVICE - By providing an implantation blocking material on the gate electrode structures of advanced semiconductor devices during high energy implantation processes, the required shielding effect with respect to the channel regions of the transistors may be accomplished. In a later manufacturing stage, the implantation blocking portion may be removed to reduce the gate electrode height to a desired level in order to enhance the process conditions during the deposition of an interlayer dielectric material, thereby significantly reducing the risk of creating irregularities, such as voids, in the interlayer dielectric material, even in densely packed device regions. | 04-30-2009 |
20090140348 | METHOD AND A SEMICONDUCTOR DEVICE COMPRISING A PROTECTION LAYER FOR REDUCING STRESS RELAXATION IN A DUAL STRESS LINER APPROACH - By providing a protection layer for suppressing stress relaxation in a tensile-stressed dielectric material during a dual stress liner approach, performance of N-channel transistors may be increased, while nevertheless maintaining a high degree of compatibility with conventional dual stress liner approaches. | 06-04-2009 |
20090194789 | METHOD OF CREATING A STRAINED CHANNEL REGION IN A TRANSISTOR BY DEEP IMPLANTATION OF STRAIN-INDUCING SPECIES BELOW THE CHANNEL REGION - By incorporating a carbon species below the channel region of a P-channel transistor prior to the formation of the gate electrode structure, an efficient strain-inducing mechanism may provided, thereby enhancing performance of P-channel transistors. The position and size of the strain-inducing region may be determined on the basis of an implantation mask and respective implantation parameters, thereby providing a high degree of compatibility with conventional techniques, since the strain-inducing region may be incorporated at an early manufacturing stage, directly to respective “large area” contact elements. | 08-06-2009 |
20090218633 | CMOS DEVICE COMPRISING AN NMOS TRANSISTOR WITH RECESSED DRAIN AND SOURCE AREAS AND A PMOS TRANSISTOR HAVING A SILICON/GERMANIUM MATERIAL IN THE DRAIN AND SOURCE AREAS - A recessed transistor configuration may be provided selectively for one type of transistor, such as N-channel transistors, thereby enhancing strain-inducing efficiency and series resistance, while a substantially planar configuration or raised drain and source configuration may be provided for other transistors, such as P-channel transistors, which may also include a strained semiconductor alloy, while nevertheless providing a high degree of compatibility with CMOS techniques. For this purpose, an appropriate masking regime may be provided to efficiently cover the gate electrode of one transistor type during the formation of the corresponding recesses, while completely covering the other type of transistor. | 09-03-2009 |
20090221123 | METHOD FOR INCREASING PENETRATION DEPTH OF DRAIN AND SOURCE IMPLANTATION SPECIES FOR A GIVEN GATE HEIGHT - The thickness of drain and source areas may be reduced by a cavity etch used for refilling the cavities with an appropriate semiconductor material, wherein, prior to the epitaxial growth, an implantation process may be performed so as to allow the formation of deep drain and source areas without contributing to unwanted channel doping for a given critical gate height. In other cases, the effective ion blocking length of the gate electrode structure may be enhanced by performing a tilted implantation step for incorporating deep drain and source regions. | 09-03-2009 |
20090243049 | DOUBLE DEPOSITION OF A STRESS-INDUCING LAYER IN AN INTERLAYER DIELECTRIC WITH INTERMEDIATE STRESS RELAXATION IN A SEMICONDUCTOR DEVICE - Enhanced efficiency of a stress relaxation implantation process may be achieved by depositing a first layer of reduced thickness and relaxing the same at certain device regions, thereby obtaining an enhanced amount of substantially relaxed dielectric material in close proximity to the transistor under consideration, wherein a desired high amount of stressed dielectric material may be obtained above other transistors by performing a further deposition process. Hence, the negative effect of the highly stressed dielectric material for specific transistors, for instance in densely packed device regions, may be significantly reduced by depositing the highly stressed dielectric material in two steps with an intermediate relaxation implantation process. | 10-01-2009 |
20090274981 | METHOD OF DETECTING REPEATING DEFECTS IN LITHOGRAPHY MASKS ON THE BASIS OF TEST SUBSTRATES EXPOSED UNDER VARYING CONDITIONS - Mask defects, such as crystal growth defects and the like, may be efficiently detected and estimated at an early stage of their development by generating test images of the mask under consideration and inspecting the images on the basis of wafer inspection techniques in order to identify repeatedly occurring defects. In some illustrative embodiments, the exposure process for generating the mask images may be performed on the basis of different exposure parameters, such as exposure doses, in order to enhance the probability of detecting defects and also estimating the effect thereof depending on the varying exposure parameters. Consequently, increased reliability may be achieved compared to conventional direct mask inspection techniques. | 11-05-2009 |
20090294809 | REDUCTION OF METAL SILICIDE DIFFUSION IN A SEMICONDUCTOR DEVICE BY PROTECTING SIDEWALLS OF AN ACTIVE REGION - By protecting sidewall portions of active semiconductor regions during a silicidation process, the probability of creating nickel silicide pipes may be reduced. Consequently, yield losses caused by the shorting of PN junctions in sophisticated semiconductor devices may be reduced. | 12-03-2009 |
20090294868 | DRIVE CURRENT ADJUSTMENT FOR TRANSISTORS FORMED IN THE SAME ACTIVE REGION BY LOCALLY INDUCING DIFFERENT LATERAL STRAIN LEVELS IN THE ACTIVE REGION - The drive current capability of a pull-down transistor and a pass transistor formed in a common active region may be adjusted on the basis of a strain-inducing mechanism, such as a stressed dielectric material and a stress memorization technique, thereby providing a simplified overall geometric configuration of the active region. Hence, static RAM cells may be formed on the basis of a minimum channel length with a simplified configuration of the active region, thereby avoiding significant yield losses as may be observed in sophisticated devices in which a pronounced variation of the transistor width may be used to adjust the ratio of the drive current capabilities for the pull-down transistor and the pass transistor. | 12-03-2009 |
20090298249 | DRIVE CURRENT INCREASE IN TRANSISTORS BY ASYMMETRIC AMORPHIZATION IMPLANTATION - By providing a substantially non-damaged semiconductor region between a pre-amorphization region and the gate electrode structure, an increase of series resistance at the drain side during the re-crystallization may be reduced, thereby contributing to overall transistor performance, in particular in the linear operating mode. Thus, symmetric and asymmetric transistor architectures may be achieved with enhanced performance without unduly adding to overall process complexity. | 12-03-2009 |
20090321841 | CMOS DEVICE COMPRISING MOS TRANSISTORS WITH RECESSED DRAIN AND SOURCE AREAS AND NON-CONFORMAL METAL SILICIDE REGIONS - A non-conformal metal silicide in a transistor of recessed drain and source configuration may provide enhanced efficiency with respect to strain-inducing mechanisms, drain/source resistance and the like. For this purpose, in some cases, an amorphizing implantation process may be performed prior to the silicidation process, while in other cases an anisotropic deposition of the refractory metal may be used. | 12-31-2009 |
20090321850 | Threshold adjustment for MOS devices by adapting a spacer width prior to implantation - Different threshold voltages of transistors of the same conductivity type in a complex integrated circuit may be adjusted on the basis of different Miller capacitances, which may be accomplished by appropriately adapting a spacer width and/or performing a tilted extension implantation. Thus, efficient process strategies may be available to controllably adjust the Miller capacitance, thereby providing enhanced transistor performance of low threshold transistors while not unduly contributing to process complexity compared to conventional approaches in which threshold voltage values may be adjusted on the basis of complex halo and well doping regimes. | 12-31-2009 |
20100025782 | TECHNIQUE FOR REDUCING SILICIDE NON-UNIFORMITIES IN POLYSILICON GATE ELECTRODES BY AN INTERMEDIATE DIFFUSION BLOCKING LAYER - Threshold variability in advanced transistor elements, as well as increased leakage currents, may be reduced by incorporating a barrier material in a polysilicon gate electrode. The barrier material results in a well-controllable and well-defined metal silicide in the polysilicon gate electrode during the silicidation sequence and during the further processing by significantly reducing the diffusion of a metal species, such as nickel, into the vicinity of the gate dielectric material. | 02-04-2010 |
20100052068 | DRIVE CURRENT ADJUSTMENT FOR TRANSISTORS FORMED IN THE SAME ACTIVE REGION BY LOCALLY PROVIDING EMBEDDED STRAIN-INDUCING SEMICONDUCTOR MATERIAL IN THE ACTIVE REGION - The drive current capability of a pull-down transistor and a pass transistor formed in a common active region may be adjusted on the basis of different strain levels obtained by providing at least one embedded semiconductor alloy in the active region, thereby providing a simplified overall geometric configuration of the active region. Hence, static RAM cells may be formed on the basis of a minimum channel length with a simplified configuration of the active region, thereby avoiding significant yield losses as may be observed in sophisticated devices, in which a pronounced variation of the transistor width is conventionally used to adjust the ratio of the drive currents for the pull-down and pass transistors. | 03-04-2010 |
20100078653 | TRANSISTOR HAVING A HIGH-K METAL GATE STACK AND A COMPRESSIVELY STRESSED CHANNEL - In a manufacturing flow for adapting the band gap of the semiconductor material with respect to the work function of a metal-containing gate electrode material, a strain-inducing material may be deposited to provide an additional strain component in the channel region. For instance, a layer stack with silicon/carbon, silicon and silicon/germanium may be used for providing the desired threshold voltage for a metal gate while also providing compressive strain in the channel region. | 04-01-2010 |
20100078735 | CMOS DEVICE COMPRISING NMOS TRANSISTORS AND PMOS TRANSISTORS HAVING INCREASED STRAIN-INDUCING SOURCES AND CLOSELY SPACED METAL SILICIDE REGIONS - In a CMOS manufacturing process flow, a cap layer formed on top of a gate electrode material may be maintained throughout the entire implantation sequence for defining the drain and source regions and may be removed during an etch process in which the width of a sidewall spacer structure may be reduced so as to reduce a lateral offset of metal silicide regions and of a stressed dielectric material. Thus, overall enhanced transistor performance may be obtained while nevertheless providing a high degree of compatibility with existing CMOS process strategies. | 04-01-2010 |
20100078736 | ASYMMETRIC TRANSISTOR DEVICES FORMED BY ASYMMETRIC SPACERS AND TILTED IMPLANTATION - An asymmetric transistor configuration is disclosed in which asymmetric extension regions and/or halo regions may be combined with an asymmetric spacer structure which may be used to further adjust the overall dopant profile of the asymmetric transistor. | 04-01-2010 |
20100109012 | STRESS TRANSFER ENHANCEMENT IN TRANSISTORS BY A LATE GATE RE-CRYSTALLIZATION - A gate electrode structure of a transistor may be formed so as to exhibit a high crystalline quality at the interface formed with a gate dielectric material, while upper portions of the gate electrode may have an inferior crystalline quality. In a later manufacturing stage after implementing one or more strain-inducing mechanisms, the gate electrode may be re-crystallized, thereby providing increased stress transfer efficiency, which in turn results in an enhanced transistor performance. | 05-06-2010 |
20100109091 | RECESSED DRAIN AND SOURCE AREAS IN COMBINATION WITH ADVANCED SILICIDE FORMATION IN TRANSISTORS - During the manufacturing process for forming sophisticated transistor elements, the gate height may be reduced and a recessed drain and source configuration may be obtained in a common etch sequence prior to forming respective metal silicide regions. Since the corresponding sidewall spacer structure may be maintained during the etch sequence, controllability and uniformity of the silicidation process in the gate electrode may be enhanced, thereby obtaining a reduced degree of threshold variability. Furthermore, the recessed drain and source configuration may provide reduced overall series resistance and enhanced stress transfer efficiency. | 05-06-2010 |
20100133628 | HIGH-K GATE ELECTRODE STRUCTURE FORMED AFTER TRANSISTOR FABRICATION BY USING A SPACER - During a replacement gate approach, the inverse tapering of the opening obtained after removal of the polysilicon material may be reduced by depositing a spacer layer and forming corresponding spacer elements on inner sidewalls of the opening. Consequently, the metal-containing gate electrode material and the high-k dielectric material may be deposited with enhanced reliability. | 06-03-2010 |
20100190309 | METHOD FOR ADJUSTING THE HEIGHT OF A GATE ELECTRODE IN A SEMICONDUCTOR DEVICE - By providing an implantation blocking material on the gate electrode structures of advanced semiconductor devices during high energy implantation processes, the required shielding effect with respect to the channel regions of the transistors may be accomplished. In a later manufacturing stage, the implantation blocking portion may be removed to reduce the gate electrode height to a desired level in order to enhance the process conditions during the deposition of an interlayer dielectric material, thereby significantly reducing the risk of creating irregularities, such as voids, in the interlayer dielectric material, even in densely packed device regions. | 07-29-2010 |
20100193873 | INCREASED DEPTH OF DRAIN AND SOURCE REGIONS IN COMPLEMENTARY TRANSISTORS BY FORMING A DEEP DRAIN AND SOURCE REGION PRIOR TO A CAVITY ETCH - Deep drain and source regions of an N-channel transistor may be formed through corresponding cavities, which may be formed together with cavities of a P-channel transistor, wherein the lateral offsets of the cavities may be adjusted on the basis of an appropriate reverse spacer regime. Consequently, the dopant species in the N-channel transistor extends down to a specific depth, for instance down to the buried insulating layer of an SOI device, while at the same time providing an efficient strain-inducing mechanism for the P-channel transistor with a highly efficient overall manufacturing process flow. | 08-05-2010 |
20100193882 | IN SITU FORMED DRAIN AND SOURCE REGIONS INCLUDING A STRAIN-INDUCING ALLOY AND A GRADED DOPANT PROFILE - The dopant profile of a transistor may be obtained on the basis of an in situ doped strain-inducing semiconductor alloy wherein a graded dopant concentration may be established along the height direction. Consequently, the semiconductor alloy may be positioned in close proximity to the channel region, thereby enhancing the overall strain-inducing efficiency, while not unduly compromising the finally obtained dopant profile. Furthermore, additional implant species may be incorporated prior to selectively growing the semiconductor alloy, thereby avoiding implantation-induced relaxation of the internal strain. | 08-05-2010 |
20100289081 | REDUCED SILICON THICKNESS OF N-CHANNEL TRANSISTORS IN SOI CMOS DEVICES - In sophisticated SOI devices, the thickness of the active semiconductor layer in the N-channel transistor may be reduced compared to the P-channel transistor for a given transistor configuration, thereby obtaining a significant increase in performance of the N-channel transistor without negatively affecting performance of the P-channel transistor. | 11-18-2010 |
20110049641 | STRESS ADJUSTMENT IN STRESSED DIELECTRIC MATERIALS OF SEMICONDUCTOR DEVICES BY STRESS RELAXATION BASED ON RADIATION - In sophisticated semiconductor devices, an efficient adjustment of an intrinsic stress level of dielectric materials, such as contact etch stop layers, may be accomplished by selectively exposing the dielectric material to radiation, such as ultraviolet radiation. Consequently, different stress levels may be efficiently obtained without requiring sophisticated stress relaxation processes based on ion implantation, which typically leads to significant device failures. | 03-03-2011 |
20110073875 | OPTICAL SIGNAL TRANSFER IN A SEMICONDUCTOR DEVICE BY USING MONOLITHIC OPTO-ELECTRONIC COMPONENTS - In a semiconductor device, optical signal transfer capabilities are implemented on the basis of silicon-based monolithic opto-electronic components in combination with an appropriate waveguide. Thus, in complex circuitries, such as microprocessors and the like, superior performance may be obtained in terms of signal propagation delay, while at the same time thermal requirements may be less critical. | 03-31-2011 |
20110076028 | SEMICONDUCTOR DEVICE COMPRISING A BURIED WAVEGUIDE FOR DEVICE INTERNAL OPTICAL COMMUNICATION - In an integrated circuit device, such as a microprocessor, a device internal optical communication system is provided in order to enhance signal transfer capabilities while relaxing overall thermal conditions. Furthermore, the device internal optical data or signal transfer capabilities may result in superior operating speed and a high degree of design flexibility. The optical communication system may be applied as a chip internal system in single chip systems or as an inter-chip optical system in three-dimensional chip configurations provided in a single package. | 03-31-2011 |
20110101427 | TRANSISTOR INCLUDING A HIGH-K METAL GATE ELECTRODE STRUCTURE FORMED PRIOR TO DRAIN/SOURCE REGIONS ON THE BASIS OF A SUPERIOR IMPLANTATION MASKING EFFECT - When forming a sophisticated high-k metal gate stack in an early manufacturing stage, the dielectric cap layer may be efficiently removed without unduly affecting the drain and source extension regions. To this end, a specifically designed sidewall spacer structure may be used, such as a silicon dioxide spacer element in combination with a silicon nitride etch stop liner. The spacer structure may thus enable the removal of the dielectric cap layer while still maintaining the functions of an implantation mask and a silicidation mask during the further processing. | 05-05-2011 |
20110101456 | STRAIN ENGINEERING IN THREE-DIMENSIONAL TRANSISTORS BASED ON GLOBALLY STRAINED SEMICONDUCTOR BASE LAYERS - Non-planar transistors, such as FINFETs, may be formed on the basis of a globally strained semiconductor material, thereby preserving a high uniaxial strain component in the resulting semiconductor fins. In this manner, a significant performance enhancement may be achieved without adding process complexity when implementing FINFET transistors. | 05-05-2011 |
20110127614 | REDUCING THE SERIES RESISTANCE IN SOPHISTICATED TRANSISTORS BY EMBEDDING METAL SILICIDE CONTACT REGIONS RELIABLY INTO HIGHLY DOPED SEMICONDUCTOR MATERIAL - In sophisticated transistor elements, an additional silicon-containing semiconductor material may be provided after forming the drain and source extension regions, thereby reducing the probability of forming metal silicide regions, such as nickel silicide regions, which may extend into the channel region, thereby causing a significant increase in series resistance. Consequently, an increased degree of flexibility in adjusting the overall transistor characteristics may be achieved, for instance, by selecting a reduced spacer width and the like. | 06-02-2011 |
20110156099 | ENHANCED CONFINEMENT OF SENSITIVE MATERIALS OF A HIGH-K METAL GATE ELECTRODE STRUCTURE - When forming sophisticated high-k metal gate electrode structures, the removal of a dielectric cap material may be accomplished with superior process uniformity by using a silicon dioxide material. In other illustrative embodiments, an enhanced spacer regime may be applied, thereby also providing superior implantation conditions for forming drain and source extension regions and drain and source regions. | 06-30-2011 |
20110156153 | PREDOPED SEMICONDUCTOR MATERIAL FOR A HIGH-K METAL GATE ELECTRODE STRUCTURE OF P- AND N-CHANNEL TRANSISTORS - In a process strategy for forming high-k metal gate electrode structures in an early manufacturing phase, a predoped semiconductor material may be used in order to reduce the Schottky barrier between the semiconductor material and the conductive cap material of the gate electrode structures. Due to the substantially uniform material characteristics of the predoped semiconductor material, any patterning-related non-uniformities during the complex patterning process of the gate electrode structures may be reduced. The predoped semiconductor material may be used for gate electrode structures of complementary transistors. | 06-30-2011 |
20110156154 | HIGH-K METAL GATE ELECTRODE STRUCTURES FORMED AT DIFFERENT PROCESS STAGES OF A SEMICONDUCTOR DEVICE - Sophisticated high-k metal gate electrode structures are provided on the basis of a hybrid process strategy in which the work function of certain gate electrode structures is adjusted in an early manufacturing stage, while, in other gate electrode structures, the initial gate stack is used as a dummy material and is replaced in a very advanced manufacturing stage. In this manner, superior overall process robustness in combination with enhanced device performance may be achieved. | 06-30-2011 |
20110159657 | ENHANCED INTEGRITY OF A HIGH-K METAL GATE ELECTRODE STRUCTURE BY USING A SACRIFICIAL SPACER FOR CAP REMOVAL - In a process strategy for forming sophisticated high-k metal gate electrode structures in an early manufacturing phase, the dielectric cap material may be removed on the basis of a protective spacer element, thereby ensuring integrity of a silicon nitride sidewall spacer structure, which may preserve integrity of sensitive gate materials and may also determine the lateral offset of a strain-inducing semiconductor material. | 06-30-2011 |
20110186915 | REPLACEMENT GATE APPROACH BASED ON A REVERSE OFFSET SPACER APPLIED PRIOR TO WORK FUNCTION METAL DEPOSITION - In a replacement gate approach, a spacer may be formed in the gate opening after the removal of the placeholder material, thereby providing a superior cross-sectional shape upon forming any electrode metals in the gate opening. Moreover, the spacer may be used for reducing the gate length, while not requiring more complex gate patterning strategies. | 08-04-2011 |
20110201165 | CMOS DEVICE COMPRISING MOS TRANSISTORS WITH RECESSED DRAIN AND SOURCE AREAS AND NON-CONFORMAL METAL SILICIDE REGIONS - A non-conformal metal silicide in a transistor of recessed drain and source configuration may provide enhanced efficiency with respect to strain-inducing mechanisms, drain/source resistance and the like. For this purpose, in some cases, an amorphizing implantation process may be performed prior to the silicidation process, while in other cases an anisotropic deposition of the refractory metal may be used. | 08-18-2011 |
20110210398 | TRANSISTORS COMPRISING HIGH-K METAL GATE ELECTRODE STRUCTURES AND ADAPTED CHANNEL SEMICONDUCTOR MATERIALS - In sophisticated semiconductor devices, a replacement gate approach may be applied, in which a channel semiconductor material may be provided through the gate opening prior to forming the gate dielectric material and the electrode metal. In this manner, specific channel materials may be provided in a late manufacturing stage for different transistor types, thereby providing superior transistor performance and superior flexibility in adjusting the electronic characteristics of the transistors. | 09-01-2011 |
20110211394 | FIELD EFFECT TRANSISTORS FOR A FLASH MEMORY COMPRISING A SELF-ALIGNED CHARGE STORAGE REGION - Storage transistors for flash memory areas in semiconductor devices may be provided on the basis of a self-aligned charge storage region. To this end, a floating spacer element may be provided in some illustrative embodiments, while, in other cases, the charge storage region may be efficiently embedded in the electrode material in a self-aligned manner during a replacement gate approach. Consequently, enhanced bit density may be achieved, since additional sophisticated lithography processes for patterning the charge storage region may no longer be required. | 09-01-2011 |
20110223732 | THRESHOLD ADJUSTMENT FOR MOS DEVICES BY ADAPTING A SPACER WIDTH PRIOR TO IMPLANTATION - Different threshold voltages of transistors of the same conductivity type in a complex integrated circuit may be adjusted on the basis of different Miller capacitances, which may be accomplished by appropriately adapting a spacer width and/or performing a tilted extension implantation. Thus, efficient process strategies may be available to controllably adjust the Miller capacitance, thereby providing enhanced transistor performance of low threshold transistors while not unduly contributing to process complexity compared to conventional approaches in which threshold voltage values may be adjusted on the basis of complex halo and well doping regimes. | 09-15-2011 |
20120091535 | Method and Semiconductor Device Comprising a Protection Layer for Reducing Stress Relaxation in a Dual Stress Liner Approach - By providing a protection layer for suppressing stress relaxation in a tensile-stressed dielectric material during a dual stress liner approach, performance of N-channel transistors may be increased, while nevertheless maintaining a high degree of compatibility with conventional dual stress liner approaches. | 04-19-2012 |
20120171830 | ASYMMETRIC TRANSISTOR DEVICES FORMED BY ASYMMETRIC SPACERS AND TILTED IMPLANTATION - An asymmetric transistor configuration is disclosed in which asymmetric extension regions and/or halo regions may be combined with an asymmetric spacer structure which may be used to further adjust the overall dopant profile of the asymmetric transistor. | 07-05-2012 |
20120256240 | METHOD FOR INCREASING PENETRATION DEPTH OF DRAIN AND SOURCE IMPLANTATION SPECIES FOR A GIVEN GATE HEIGHT - The thickness of drain and source areas may be reduced by a cavity etch used for refilling the cavities with an appropriate semiconductor material, wherein, prior to the epitaxial growth, an implantation process may be performed so as to allow the formation of deep drain and source areas without contributing to unwanted channel doping for a given critical gate height. In other cases, the effective ion blocking length of the gate electrode structure may be enhanced by performing a tilted implantation step for incorporating deep drain and source regions. | 10-11-2012 |
20130240988 | TRANSISTORS COMPRISING HIGH-K METAL GATE ELECTRODE STRUCTURES AND EMBEDDED STRAIN-INDUCING SEMICONDUCTOR ALLOYS FORMED IN A LATE STAGE - In sophisticated semiconductor devices, replacement gate approaches may be applied in combination with a process strategy for implementing a strain-inducing semiconductor material, wherein superior proximity of the strain-inducing semiconductor material and/or superior robustness of the replacement gate approach may be achieved by forming the initial gate electrode structures with superior uniformity and providing at least one cavity for implementing the strained channel regions in a very advanced manufacturing stage, i.e., after completing the basic transistor configuration. | 09-19-2013 |
20130252409 | HIGH-K GATE ELECTRODE STRUCTURE FORMED AFTER TRANSISTOR FABRICATION BY USING A SPACER - During a replacement gate approach, the inverse tapering of the opening obtained after removal of the polysilicon material may be reduced by depositing a spacer layer and forming corresponding spacer elements on inner sidewalls of the opening. Consequently, the metal-containing gate electrode material and the high-k dielectric material may be deposited with enhanced reliability. | 09-26-2013 |
20130299891 | FIELD EFFECT TRANSISTORS FOR A FLASH MEMORY COMPRISING A SELF-ALIGNED CHARGE STORAGE REGION - Storage transistors for flash memory areas in semiconductor devices may be provided on the basis of a self-aligned charge storage region. To this end, a floating spacer element may be provided in some illustrative embodiments, while, in other cases, the charge storage region may be efficiently embedded in the electrode material in a self-aligned manner during a replacement gate approach. Consequently, enhanced bit density may be achieved, since additional sophisticated lithography processes for patterning the charge storage region may no longer be required. | 11-14-2013 |
20140238045 | SEMICONDUCTOR DEVICE COMPRISING A STACKED DIE CONFIGURATION INCLUDING AN INTEGRATED PELTIER ELEMENT - A method of controlling temperature in a semiconductor device that includes a stacked device configuration is disclosed. The method includes providing a Peltier element having a metal-based heat sink formed above a first substrate of the stacked device configuration and a metal-based heat source formed above a second substrate of the stacked device configuration, and establishing a current flow through the Peltier element when the semiconductor device is in a specified operating phase. | 08-28-2014 |