1. Field of the Invention
Generally, the present disclosure relates to the fabrication of highly sophisticated integrated circuits including advanced transistor elements that comprise gate structures of increased capacitance including a high-k gate dielectric material.
2. Description of the Related Art
The fabrication of advanced integrated circuits, such as CPUs, storage devices, ASICs (application specific integrated circuits) and the like, requires the formation of a large number of circuit elements on a given chip area according to a specified circuit layout. In a wide variety of integrated circuits, field effect transistors represent one important type of circuit element that substantially determines performance of the integrated circuits. Generally, a plurality of process technologies are currently practiced for forming field effect transistors, wherein, for many types of complex circuitry, CMOS technology is one of the most promising approaches due to the superior characteristics in view of operating speed and/or power consumption and/or cost efficiency. During the fabrication of complex integrated circuits using CMOS technology, millions of transistors, i.e., N-channel transistors and P-channel transistors, are formed on a substrate including a crystalline semiconductor layer. A field effect transistor, irrespective of whether an N-channel transistor or a P-channel transistor is considered, typically comprises so-called PN junctions that are formed by an interface of highly doped regions, referred to as drain and source regions, with a slightly doped or non-doped region, such as a channel region, disposed adjacent to the highly doped regions. In a field effect transistor, the conductivity of the channel region, i.e., the drive current capability of the conductive channel, is controlled by a gate electrode formed adjacent to the channel region and separated therefrom by a thin insulating layer. The conductivity of the channel region, upon formation of a conductive channel due to the application of an appropriate control voltage to the gate electrode, depends on, among other things, the mobility of the charge carriers in the channel region.
The continuous shrinkage of critical dimensions of transistor elements has resulted in a gate length of field effect transistors of 50 nm and significantly less, thereby providing sophisticated semiconductor devices having enhanced performance and an increased packing density. The increase of electrical performance of the transistors is strongly correlated with a reduction of the channel length, which may result in an increased drive current and switching speed of the field effect transistors. On the other hand, the reduction of the channel length is associated with a plurality of tissues in terms of channel controllability and static leakage currents of these transistors. It is well known that field effect transistors with a very short channel may require an increased capacitive coupling between the gate electrode structure and the channel region in order to provide the desired static and dynamic current flow controllability. Typically, the capacitive coupling is increased by reducing the thickness of the gate dielectric material, which is typically formed on the basis of a silicon dioxide-based material, possibly in combination with a nitrogen species, due to the superior characteristics of a silicon/silicon dioxide interface. Upon implementing a channel length of the above-identified order of magnitude, however, the thickness of the silicon dioxide-based gate dielectric material may reach values of 1.5 nm and less, which in turn may result in significant leakage currents due to a direct tunneling of the charge carriers through the very thin gate dielectric material. Since the exponential increase of the leakage currents upon further reducing the thickness of silicon dioxide-based gate dielectric materials is not compatible with the thermal power design requirements, other mechanisms have been developed so as to further enhance transistor performance and/or reduce the overall transistor dimensions.
For example, by creating a certain strain component in the channel region of silicon-based transistor elements, the charge carrier mobility and, thus, the overall conductivity of the channel may be enhanced. For a silicon material with a standard crystallographic configuration, i.e., a (100) surface orientation with the channel length direction oriented along a <110> equivalent direction, tensile strain in the current flow direction may enhance conductivity of electrons, thereby improving transistor performance of N-channel transistors. On the other hand, generating a compressive strain in the current flow direction may increase the mobility of holes and may, thus, provide superior conductivity in P-channel transistors. Consequently, a plurality of strain-inducing mechanisms have been developed in the past, which per se require a complex manufacturing sequence for implementing these techniques. Upon further device scaling, “internal” strain-inducing sources, such as an embedded strain-inducing semiconductor material, may represent a very efficient strain-inducing mechanism. For example, frequently the incorporation of a compressive strain-inducing silicon/germanium alloy in the drain and source areas of P-channel transistors is applied in order to enhance performance of these transistors. For this purpose, in an early manufacturing stage, cavities are formed in the active region laterally adjacent to the gate electrode structure of the P-channel transistor, while the N-channel transistors are covered by a spacer layer. These cavities may be subsequently refilled with the silicon/germanium alloy on the basis of selective epitaxial growth techniques. During the etch process for forming the cavities and during the subsequent epitaxial growth process, the gate electrode of the P-channel transistor has to be encapsulated in order to not unduly expose sensitive materials of the gate electrode structure, such as a silicon-based electrode material, to the process ambient for forming the cavities and for selectively growing the silicon/germanium alloy. Thereafter, the gate electrode structures may be exposed and the further processing may be continued by forming drain and source regions in accordance with any appropriate process strategy.
Basically, the above-described strain-inducing mechanism is a very efficient concept for improving transistor performance of P-channel transistors, wherein the efficiency of the finally obtained strain in the channel region of the transistor, however, strongly depends on the internal strain level of the semiconductor alloy and on the lateral offset of this material from the channel region. Typically, the material composition of the strain-inducing semiconductor alloy is restricted by currently available sophisticated selective epitaxial deposition recipes, which in the case of a silicon/germanium alloy may presently not allow germanium concentrations of more than approximately 30 atomic percent. Consequently, a further improvement of the total strain in the channel region requires a reduction of the lateral offset of the silicon/germanium alloy from the channel region so that any protective spacer structures may have to be provided with a reduced width.
In addition to providing strain-inducing mechanisms in sophisticated field effect transistors, also sophisticated gate electrode materials have been proposed in order to overcome the restrictions of conventional silicon dioxide/polysilicon-based gate electrode structures. To this end, the conventional silicon dioxide-based gate dielectric material is replaced, at least partially, by a so-called high-k dielectric material, i.e., a dielectric material having a dielectric constant of 10.0 and higher, which may result in a desired high capacitance between the gate electrode and the channel region, while nevertheless a certain minimum physical thickness is provided so as to keep the resulting leakage currents at an acceptable level. For this purpose, a plurality of dielectric materials, such as hafnium oxide-based materials, zirconium oxide, aluminum oxide and the like, are available and may be used in sophisticated gate electrode structures. Furthermore, the polysilicon material may also be replaced, at least in the vicinity of the gate dielectric material, since typically polysilicon suffers from charge carrier depletion in the vicinity of the gate dielectric material, which may reduce the effective capacitance. Moreover, with sophisticated high-k gate dielectric materials, the work function of standard polysilicon materials and a corresponding doping may no longer be sufficient to provide the required electronic characteristics of the gate electrode material in order to obtain a desired threshold voltage of the transistors under consideration. For this reason, specific work function adjusting metal species, such as aluminum, lanthanum and the like, are typically incorporated in the gate dielectric material and/or in an appropriate electrode material in order to obtain a desired work function and also increase conductivity of the gate electrode material at least in the vicinity of the gate dielectric material.
Thus, a plurality of sophisticated process strategies have been developed, wherein, in some promising approaches, the sophisticated gate materials, such as a high-k dielectric material and a metal-containing electrode material, possibly including a work function adjusting metal species, may be provided in an early manufacturing stage in combination with a polysilicon material, thereby providing a high degree of compatibility with conventional process strategies for forming sophisticated field effect transistors. It turns out, however, that a reliable confinement of the sensitive material system including the high-k dielectric material and the metal-containing electrode material has to be guaranteed in order to avoid a shift in threshold voltage or any other variabilities of the sophisticated high-k metal gate electrode structures.
In an attempt to further enhance device performance of sophisticated field effect transistors, it has been proposed to combine sophisticated high-k metal gate electrode structures with a strain-inducing mechanism, for instance, by incorporating a strain-inducing semiconductor alloy in the active regions of the transistors. In this case, the encapsulation of the gate electrode structure of the transistor, which may require the incorporation of an embedded strain-inducing semiconductor alloy, may have to be implemented on the basis of detrimental requirements. On the one hand, the confinement of the gate electrode structure has to ensure integrity of the sensitive material system, for example, prior to, during and after the incorporation of the strain-inducing semiconductor material, and, on the other hand, a reduced thickness of any protective spacer elements, such as silicon nitride-based materials, is to be selected with reduced width in view of enhancing efficiency of the strain-inducing mechanism. Consequently, a compromise of thickness of the spacer elements and gain in performance of sophisticated transistors is typically applied.
In many conventional approaches, however, overall defectivity during the patterning of the sophisticated high-k metal gate electrode structures may require efficient wet chemical cleaning processes. For this purpose, an SPM (mixture of sulfuric acid and hydrogen peroxide) solution has proven to be a very efficient cleaning agent, which, however, “efficiently” removes metal-containing electrode materials, such as titanium nitride, as are provided in the sophisticated gate electrode structure. Omitting the cleaning step on the basis of SPM or providing a less efficient cleaning recipe may significantly increase the overall defectivity, thereby resulting in a significant yield loss. Using efficient SPM cleaning solutions, however, may result in significant gate failures in sophisticated semiconductor designs, as will be described in more detail with reference to
a schematically illustrates a top view of a semiconductor device 100 according to a complex design. As shown, the device 100 or its design comprises an active region 102A, which is to be understood as a semiconductor region in which one or more transistors are to be formed. For example, the active region 102A is illustrated to comprise three transistors 150A including respective gate electrode structures 130A. The gate electrode structures 130A may include a complex material system including a high-k dielectric material and a metal-containing electrode material, as discussed above. Basically, the gate electrode structures 130A represent conductive lines extending across the active region 102A and are typically formed with an end portion thereof on an isolation region 102C, which laterally delineates the active region 102A and any other active regions (not shown). Moreover, according to design requirements, a gate electrode structure 130C may also extend above the isolation region 102C in close proximity to the active region 102A. It should be appreciated that a length of the gate electrode structures 130A, 130C may be 50 nm and less in sophisticated applications so that the distance between the gate electrode structure 130C and the active region 102A may be significantly less than the critical gate length. Furthermore, the transistors 150A may represent devices that require the incorporation of a strain-inducing semiconductor material, such as a silicon/germanium alloy, possibly in combination with a semiconductor alloy for appropriately adjusting the threshold voltage of the transistors 150A.
Consequently, upon forming the device 100 according to the geometric configuration as shown in
b schematically illustrates a cross-sectional view of a semiconductor device 100 according to the section indicated as Ib in
c schematically illustrates a cross-sectional view along the section Ic of
The semiconductor device 100 as shown in
With reference to
d schematically illustrates the device 100 during an etch process 103 for forming cavities 103A in the active region 102A adjacent to the isolation region 102C. As illustrated, the cap materials 133 and the liner 134 may act as an etch mask.
e schematically illustrates the device 100 during a cleaning process 104 in order to remove any etch byproducts and other contaminants, thereby, however, also contributing to a certain material erosion at exposed sidewall surface areas in the cavities 103A.
f schematically illustrates the semiconductor device 100 during a further cleaning process 106, which is typically performed prior to starting a selective epitaxial growth process in order to remove native oxides and the like. On the other hand, a certain degree of material erosion may occur in the cavities 103A so that a sidewall surface area 131S of the sensitive material system 131 may be exposed below the sidewall spacer structure 134 of the gate electrode structure 130C. Consequently, sensitive materials may be attacked and may be removed, depending on the cleaning or etch chemistry used. Furthermore, during the further processing, for instance upon epitaxially growing a strain-inducing semiconductor alloy in the cavities 103A, the sidewalls may not be efficiently covered, thereby even further contributing to material deterioration of the system 131 during the further processing.
Similarly, the recessed configuration of the isolation region 102C at or near the end portions of the gate electrode structure 130C may also result in an exposure of any sensitive materials, thereby causing a significant shift of the overall material characteristics.
In view of the situation described above, the present disclosure relates to manufacturing techniques and semiconductor devices in which sophisticated high-k metal gate electrode structures may be formed in an early manufacturing stage, while avoiding or at least reducing the effects of one or more of the problems identified above.
The following presents a simplified summary of the invention in order to provide a basic understanding of some aspects of the invention. This summary is not an exhaustive overview of the invention. It is not intended to identify key or critical elements of the invention or to delineate the scope of the invention. Its sole purpose is to present some concepts in a simplified form as a prelude to the more detailed description that is discussed later.
Generally, the present disclosure provides manufacturing techniques and semiconductor devices in which recessed areas or divots in sophisticated trench isolation regions may be reduced in depth or may be substantially completely filled after completing the trench isolation process. To this end, an appropriate fill material may be locally provided in the recessed area, thereby achieving an improved surface topography for the further processing of the device. Consequently, critical process steps, such as the encapsulation of sophisticated high-k metal gate electrode structures, may be accomplished, thereby significantly improving overall production yield and device uniformity due to a significant reduction of gate failures or a shift of transistor characteristics. In some illustrative embodiments disclosed herein, the fill material may be provided on the basis of a high quality silicon oxide material, which may be efficiently incorporated into the recessed areas by a deposition process, while the final material characteristics may be established on the basis of a subsequent anneal process. Hence, well-established process techniques may be applied for forming sophisticated trench isolation regions, while nevertheless enhanced process robustness in subsequent critical process steps may be achieved.
One illustrative method disclosed herein comprises forming a trench isolation region in a semiconductor layer of a semiconductor device, wherein the trench isolation region laterally delineates an active region in the semiconductor layer. The method further comprises forming a fill material selectively in a recessed area of the trench isolation region. Moreover, the method comprises forming a gate electrode structure on the active region and the trench isolation region that includes the fill material.
A further illustrative method disclosed herein comprises forming a trench isolation region in a semiconductor layer of a semiconductor device so as to laterally delineate an active region, wherein the trench isolation region comprises a recessed area adjacent to the active region. The method further comprises reducing a depth of the recessed area of the trench isolation region and forming a gate electrode structure on the trench isolation region, wherein the gate electrode structure comprises a high-k dielectric material.
One illustrative semiconductor device disclosed herein comprises a trench isolation region that laterally delineates an active region in a semiconductor layer. The trench isolation region comprises a first dielectric material and a second dielectric material that is locally formed adjacent to the active region. The semiconductor device further comprises a gate electrode structure formed on a channel area of the active region, wherein the gate electrode structure comprises a material system comprising a high-k dielectric material and a metal-containing electrode material. The gate electrode structure further comprises a protective liner formed on sidewalls of the high-k dielectric material and the metal-containing electrode material.
The disclosure may be understood by reference to the following description taken in conjunction with the accompanying drawings, in which like reference numerals identify like elements, and in which:
a schematically illustrates a top view of a semiconductor device wherein a high-k metal gate electrode structure is formed on the basis of a conventional process strategy with recessed areas formed on edge areas of trench isolation regions adjacent to active regions;
b-1f schematically illustrate cross-sectional views of the semiconductor device during various manufacturing stages in which an encapsulation of the high-k metal gate electrode structure is performed on the basis of the recessed areas in the trench isolation regions, thereby causing significant yield loss;
a-2d schematically illustrate cross-sectional views of a semiconductor device during various manufacturing stages after completing a trench isolation region based on well-established process techniques, wherein any divots or recessed areas adjacent to any active regions may be reduced in depth or may be substantially completely filled with an appropriate fill material, according to illustrative embodiments;
e-2f schematically illustrate cross-sectional views of the semiconductor device according to further illustrative embodiments in which a fill material may be provided on the basis of an etch stop liner so as to provide superior process control and integrity of active regions; and
g-2h schematically illustrate cross-sectional views of the semiconductor device in further advanced manufacturing stages in which sophisticated high-k metal gate electrode structures may be reliably encapsulated on the basis of the superior surface topography of the trench isolation regions, according to still further illustrative embodiments.
While the subject matter disclosed herein is susceptible to various modifications and alternative forms, specific embodiments thereof have been shown by way of example in the drawings and are herein described in detail. It should be understood, however, that the description herein of specific embodiments is not intended to limit the invention to the particular forms disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.
Various illustrative embodiments of the invention are described below. In the interest of clarity, not all features of an actual implementation are described in this specification. It will of course be appreciated that in the development of any such actual embodiment, numerous implementation-specific decisions must be made to achieve the developers' specific goals, such as compliance with system-related and business-related constraints, which will vary from one implementation to another. Moreover, it will be appreciated that such a development effort might be complex and time-consuming, but would nevertheless be a routine undertaking for those of ordinary skill in the art having the benefit of this disclosure.
The present subject matter will now be described with reference to the attached figures. Various structures, systems and devices are schematically depicted in the drawings for purposes of explanation only and so as to not obscure the present disclosure with details that are well known to those skilled in the art. Nevertheless, the attached drawings are included to describe and explain illustrative examples of the present disclosure. The words and phrases used herein should be understood and interpreted to have a meaning consistent with the understanding of those words and phrases by those skilled in the relevant art. No special definition of a term or phrase, i.e., a definition that is different from the ordinary and customary meaning as understood by those skilled in the art, is intended to be implied by consistent usage of the term or phrase herein. To the extent that a term or phrase is intended to have a special meaning, i.e., a meaning other than that understood by skilled artisans, such a special definition will be expressly set forth in the specification in a definitional manner that directly and unequivocally provides the special definition for the term or phrase.
The present disclosure generally contemplates manufacturing techniques and semiconductor devices in which the problem of gate failures or significant shifts in transistor characteristics may be addressed by reducing the surface topography of trench isolation regions prior to forming sophisticated gate electrode structures. As discussed above, typically, sophisticated lithography and etch strategies have to be applied in forming an appropriate hard mask material and etching into the semiconductor material in order to define the lateral size, position and shape of the trench isolation regions. Thereafter, complex deposition processes and anneal sequences are applied and any excess materials are removed together with the hard mask material or materials, thereby producing a surface topography in which pronounced recessed areas are formed adjacent to the active regions. These recessed areas or divots may significantly influence the further processing of the device, as is, for instance, described above with reference to the semiconductor device 100. Due to the significant yield loss, which is believed to be caused by the presence of the recessed areas, great efforts have been made in order to avoid the creation of the recessed areas upon forming the trench isolation regions. It turns out, however, that many of these approaches may require different dielectric materials to be used, while in other cases highly complex process modifications may have to be implemented, thereby contributing to increased process complexity, while also the compatibility with subsequent process techniques may not be ensured for at least some of such approaches. According to the principles disclosed herein, however, well-established material characteristics and manufacturing techniques used for forming sophisticated trench isolation regions may be preserved, while on the other hand the surface topography may be significantly reduced in a subsequent process sequence by reducing the depth of the recessed areas, while at the same time desired material characteristics of the trench isolation regions are achieved. To this end, in some illustrative embodiments, an appropriate fill material, for instance a silicon oxide material, may be efficiently deposited into the recessed areas and may be densified so as to obtain similar material characteristics compared to the actual dielectric material of the trench isolation regions obtained after completing the trench formation module.
In other illustrative embodiments, superior process control upon removing any excess portion of the additional fill material may be achieved by providing a stop liner, which may be used to control a removal process, such as a chemical mechanical polishing (CMP) process, thereby avoiding undue recessing of the additional fill material. On the other hand, the stop liner may be efficiently removed by highly selective wet chemical etch recipes substantially without affecting the previously formed fill material. Also in this manner, the fill material may be provided with the desired material composition, for instance substantially with the same stoichiometric composition compared to the actual fill material of the trench isolation region, while the presence of the stop material in the recessed areas of the trench isolation region may not negatively influence the overall device characteristics.
With reference to
a schematically illustrates a cross-sectional view of a semiconductor device 200 in a manufacturing stage in which a trench isolation region may be provided in a semiconductor layer. As shown, the device 200 may comprise a substrate 201 and a semiconductor layer 202 which, as also discussed above with reference to the semiconductor device 100, may form an SOI configuration when a buried insulating material is formed below the semiconductor layer 202, or which may form a bulk configuration when the semiconductor layer 202 is directly in contact with a crystalline semiconductor material of the substrate 201. Furthermore, a trench isolation region 202C laterally delineates active regions 202A, 202B, thereby appropriately defining the position, the lateral size and shape of the active regions 202A, 202B. The isolation region 202C may comprise any appropriate dielectric material 220, such as a silicon oxide material, having an appropriate density and thus a moderately high etch resistivity during the further processing of the device 200. As previously discussed, the trench isolation region 202C may comprise divots or recessed areas 202D in the vicinity of the active regions 202A, 202B.
The device 200 as shown in
b schematically illustrates the device 200 in a further advanced manufacturing stage. As shown, a deposition process 223A may be performed so as to deposit a cap layer 223, which may substantially completely fill the recessed areas 202D, while also forming a substantially uniform layer on top of any horizontal device areas. The deposition process 223A may be performed on the basis of CVD techniques, wherein the material growth on the various sidewalls of the recessed areas 202D, indicated as 202S, may result in a substantially complete filling of the areas 202D, since, for a given thickness of the layer 223, the growth of the material on the sidewalls 202S may result in a “merging” of corresponding “overhangs,” thereby reliably closing the areas 202D. In some illustrative embodiments, the cap layer 223 may be formed on the basis of a material that may have substantially the same stoichiometric composition as the dielectric material 220. For example, well-established CVD recipes are available for forming a silicon oxide material.
c schematically illustrates the device 200 in a further advanced manufacturing stage in which the cap layer 223 may be exposed to elevated temperatures in the form of an anneal process 224 in order to improve the overall material characteristics of the cap layer 223. To this end, in some illustrative embodiments, a process atmosphere may be established on the basis of oxygen and/or nitrogen with temperatures in the range of 800-1100° C., thereby inducing a desired densification of the material 223, when provided in the form of a silicon oxide material, which may result in material characteristics that are very similar to the material characteristics of a thermally grown silicon oxide material. Consequently, during the corresponding reduction in volume, also the material in the recessed areas 202D is appropriately densified, thereby endowing these areas with superior surface topography and enhanced etch resistivity during the further processing. In other illustrative embodiments, the anneal process 224 may be performed on the basis of a plasma, which may enable the use of lower temperatures while also achieving the desired densification of the material of the cap layer 223. For example, a plurality of plasma-based anneal techniques are available. For instance, anneal processes on the basis of uniform and highly controllable plasma conditions may be used with temperatures in the range of 300-700° C. It should be appreciated, however, that other process parameters may be readily selected by performing corresponding experiments in order to determine appropriate process parameters that may result in the desired material characteristics of the cap layer 223 prior to removing an excess portion thereof.
d schematically illustrates the device 200 during an etch process 225 in which an excess portion of the cap layer 223 (
Consequently, based on the trench isolation region 202C as shown in
e schematically illustrates the device 200 according to further illustrative embodiments. As shown, the cap layer 223 may be formed above the active regions 202A, 202B and above the trench isolation region 202C, which comprises initially the recessed areas 202D, as discussed above. In the embodiment shown, the cap layer 223 may comprise a stop liner 223L, for instance provided on the basis of a silicon nitride material, which may be provided with a thickness of one to several nanometers, depending on the overall process and device requirements. To this end, well-established highly conformal deposition recipes may be applied, such as multi-layer deposition, low pressure CVD techniques and the like, in which thin silicon nitride materials may be formed in a highly controllable manner. Consequently, any exposed surface areas and in particular the surface of the active regions 202A, 202B may be covered or masked by the stop liner 223L. Thereafter, the desired fill material 223F may be formed, for instance by corresponding deposition techniques, as described above, thereby completely filling the recessed areas 202D and providing a continuous layer above the active regions 202A, 202B and the isolation region 202C. Thereafter, if required, an anneal process may be applied, for instance as described above, in order to further densify, in particular, the fill material 223F, while in other cases the further processing may be continued without applying an anneal process.
f schematically illustrates the device 200 in a further advanced manufacturing stage. As illustrated, a material removal process 226A may be applied so as to remove an excess portion of the fill material 223F. In some illustrative embodiments, the process 226A may be performed on the basis of CMP techniques, thereby efficiently removing material of the layer 223F, while on the other hand the stop liner 223L may be used for controlling the process 226A. For example, silicon oxide material may be efficiently removed selectively with respect to silicon nitride material on the basis of a plurality of well-established CMP recipes. Hence, the fill material 223D, i.e., the remaining portion of the previously provided fill material 223F, may be preserved in the areas 202D, wherein, in particular, the local restriction of the recessed areas 202D to the immediate neighborhood of the active regions 202A, 202B may not result in significant “dishing” effects so that the recessed areas 202D may remain substantially filled with the material 223D after the removal process 226A. Thereafter, a further material removal process 226B may be applied, for instance in the form of a highly selective wet chemical etch process, for instance using hot phosphoric acid and the like, thereby efficiently etching the liner 223L without unduly affecting the active regions 202A, 202B and without unduly affecting the fill material 223D in the recessed areas 202D.
Consequently, also in this case, the further processing may be continued on the basis of a superior surface topography of the trench isolation region 202C, while on the other hand increased process flexibility may be achieved by providing the stop liner 223L.
g schematically illustrates the semiconductor device 200 in a further advanced manufacturing stage. As illustrated, a gate electrode structure 230 may be formed above the active region 202A and may also extend above a portion of the isolation region 202C, for instance in a similar configuration as previously described with reference to
In some illustrative embodiments, the gate electrode structure 230 may be formed on the basis of a threshold voltage adjusting semiconductor alloy 202E, for instance in the form of a silicon/germanium alloy, if a corresponding adaptation of the electronic characteristics is required, for instance for adjusting appropriate threshold voltage values for different types of transistors. In this case, after providing the fill material 223D and prior to forming the gate electrode structure 230, the active region 202A may be recessed, for instance on the basis of any appropriate etch strategy, and subsequently the material 202E may be grown on the basis of selective epitaxial growth techniques. Consequently, upon recessing the active region 202A, the corresponding recess may be bordered by the material 223D, which may thus provide superior growth conditions upon depositing the material 202E. That is, due to the presence of the fill material 223D in the area 202D, a lateral growth of the material 220E may be substantially avoided, thereby obtaining superior growth conditions within the entire active region 202A, which in turn results in superior uniformity of the transistor characteristics, which strongly depend on the material composition and the layer thickness of the semiconductor alloy 202E.
h schematically illustrates the semiconductor device 200 in a further advanced manufacturing stage. As shown, a transistor 250 may be formed in and above the active region 202A and may comprise a gate electrode structure 230A, while a further gate electrode structure 230C may be formed above the trench isolation region 202C in close proximity to the active region 202A, for instance according to a device configuration as is previously discussed with reference to
In some illustrative embodiments, the active region 202A may comprise a strain-inducing semiconductor material 252A, which may be formed by using process techniques as discussed above with reference to the semiconductor device 100, wherein, after the corresponding cavity etch process and the selective deposition of the material 252A, still a reliable encapsulation of the gate electrode structures 230A, 230C may be achieved. Furthermore, as described with reference to
The semiconductor device 200 as shown in
As a result, the present disclosure provides manufacturing techniques and semiconductor devices in which trench isolation regions may be formed on the basis of well-established process techniques, wherein any divots or recessed areas may be reduced in depth or may be completely filled in a subsequent process sequence prior to forming sophisticated gate electrode structures. Consequently, encapsulation of high-k metal gate electrode structures may be achieved with superior reliability, thereby avoiding or at least significantly reducing gate failures or shifts of transistor characteristics, which are conventionally caused by insufficient encapsulation and thus protection of sensitive gate materials.
The particular embodiments disclosed above are illustrative only, as the invention may be modified and practiced in different but equivalent manners apparent to those skilled in the art having the benefit of the teachings herein. For example, the process steps set forth above may be performed in a different order. Furthermore, no limitations are intended to the details of construction or design herein shown, other than as described in the claims below. It is therefore evident that the particular embodiments disclosed above may be altered or modified and all such variations are considered within the scope and spirit of the invention. Accordingly, the protection sought herein is as set forth in the claims below.
Number | Date | Country | Kind |
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10 2011 005 719.6 | Mar 2011 | DE | national |