Patent Publication Number: US-2007117326-A1

Title: Material architecture for the fabrication of low temperature transistor

Description:
BACKGROUND OF INVENTION  
      1) Field of the Invention  
      This invention relates generally to the structure and fabrication of a semiconductor device and more particularly to the fabrication of a carbon containing layer near doped regions in a transistor.  
      2) Description of the Prior Art  
      Semiconductor devices such as field effect transistors (FETs) have a source region, and a drain region formed in a semiconductor substrate and a gate formed over the channel region. The source and drain are formed in a semiconductor substrate by introducing impurities (dopants) into the substrate. The semiconductor body separates the source region and the drain region. The dopants used to form the source and drain regions are of a different polarity (n-type or p-type) than the semiconductor substrate body surrounding the source and drain regions. Consequently, substantially no current will pass from the source to the semiconductor body or from the drain to the semiconductor body.  
      There is a space-charge layer (or channel ) which separates both the source region from the semiconductor body and the drain region from the semiconductor body.  
      The usual method of introducing dopant atoms is ion implantation. During ion implantation, dopant atoms are ionized, accelerated and directed at a silicon substrate. They enter the crystal lattice of the silicon substrate, collide with silicon atoms and gradually lose energy, finally coming to rest at some depth within the lattice. The average depth can be controlled by adjusting the acceleration energy. The dopant dose can be controlled by monitoring the ion current during implantation. The principal side effect—disruption of the silicon lattice caused by ion collisions—is removed by subsequent heat treatment, i.e., annealing. Annealing is required to repair lattice damage and place dopant atoms on substitutional sites within the silicon substrate where they will be electrically active. Rapid thermal annealing is a term that covers various methods of heating wafers for short periods of time, e.g., 100 seconds, which enable almost complete electrical activation with diffusion of dopant atoms occurring within what had been previously regarded as tolerable limits.  
      However, during the anneal, damage from the ion implantation process, in the form of point defects, migrates laterally from the source and/or drain and into the semiconductor body and enhances dopant diffusion. This enhanced diffusion, known as transient enhanced diffusion (TED) changes the carefully tailored profile in the body of the device.  
      Transient enhanced diffusion occurs during post-implant annealing and arises from the fact that the diffusion of dopant atoms, particularly boron (B) and phosphorus (P), is undesirably enhanced by excess silicon (Si) self-interstitials generated by the implant. The generation of excess Si self-interstitials by the implant also leads to a phenomenon herein referred to as dynamic clustering whereby implanted dopant atoms form clusters or agglomerates in a semiconductor layer. These clusters or agglomerates are immobile and electrically inactive.  
      Recent investigations have been aimed at untangling the mechanisms of dopant diffusion in order to provide a sound basis for simulation programs designed to predict dopant diffusion during device processing. An additional challenge is the development of processing-compatible methods of controlling the diffusion of dopant atoms.  
      The  FIG. 10  shows a typical implant doping profile at different implantation energies. Rp which is the projected range of the implantation is measured from the surface of the substrate in to the maximum region where the dopant lies.  
      The more relevant technical developments in the patent literature can be gleaned by considering the following:  
      U.S. Pat. No. 6,153,920 Gossmann, et al. Nov. 28, 2000—Process for controlling dopant diffusion in a semiconductor layer and semiconductor device formed thereby.  
      U.S. Pat. No. 5,731,626 Eaglesham, et al and U.S. Pat. No. 6,043,139 Eaglesham, et al.—Process for controlling dopant diffusion in a semiconductor layer—Diffusion of ion-implanted dopant is controlled by incorporating electrically inactive impurity in a semiconductor layer by at least one crystal growth technique.  
      U.S. Pat. No. 6,576,535 Drobny, et al. Jun. 10, 2003—doped epitaxial layer.  
      Chung Foong Tan, Eng Fong Chor, Jinping Liu, Hyeokjae Lee, Elgin Quek, and Lap Chan, “Influence of substitutional carbon incorporation on implanted-indium-related defects and transient enhanced diffusion”, Applied Physics Letters Vol 83(20) pp. 4169-4171. Nov. 17, 2003.  
      Nishikawa, S., et al., “Reduction of transient boron diffusion in preamorphized Si by carbon implantation,” Appl. Phys. Lett., 60(18), May 4, 1992.  
      King et al., “Defect evolution of low energy, amorphizing germanium implanted in silicon”, Journal of Applied Physics, Vol. 93, # 5, march 2003, pp 2449-2452.  
      Nishikawa et al., “Elimination of secondary defects in preamorphized Si by C+ implantation”, Appl. Phys. Lett 62 (3) 18 Jan. 1993, pp 303-305.  
      Noda, Indium segregation into dislocation loops induced by ion implanted damage in Si”, Journal Of Applied Physics v. 93, # 3, 1 Feb. 2003, pp. 1428-1431.  
     SUMMARY OF THE INVENTION  
      Embodiments of the present invention provides a structure and a method of manufacturing a device which is characterized as follows.  
      An example embodiment is a method to form first and second regions and a carbon containing layer using implantation processes comprising:  
      forming a carbon containing layer in a substrate; said substrate comprised of crystalline structure including silicon;  
      implanting ions to form a first region and a first end-of-range region in the substrate; at least a portion of said first end-of-range region is in said carbon containing layer;  
      implanting ions to form a second region and a second end-of-range region in the substrate; at least a portion of said second region end-of-range region is in said carbon containing layer.  
      Another example embodiment is a semiconductor structure comprising:  
      first and second regions and a carbon containing layer comprising: a carbon containing layer in a substrate; said substrate comprised of crystalline structure including silicon;  
      a first region and a first end-of-range region in the substrate; said first end-of-range region is in said carbon containing layer;  
      a second region a second end-of-range region in the substrate; said second region end-of-range region in said carbon containing layer.  
      Other example embodiments are defined in the claims and specification below.  
      The above and below advantages and features are of representative embodiments only, and are not exhaustive and/or exclusive. They are presented only to assist in understanding the invention. It should be understood that they are not representative of all the inventions defined by the claims, to be considered limitations on the invention as defined by the claims, or limitations on equivalents to the claims. For instance, some of these advantages may be mutually contradictory, in that they cannot be simultaneously present in a single embodiment. Similarly, some advantages are applicable to one aspect of the invention, and inapplicable to others. Furthermore, certain aspects of the claimed invention have not been discussed herein. However, no inference should be drawn regarding those discussed herein relative to those not discussed herein other than for purposes of space and reducing repetition. Thus, this summary of features and advantages should not be considered dispositive in determining equivalence. Additional features and advantages of the invention will become apparent in the following description, from the drawings, and from the claims.  
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
      The features and advantages of a semiconductor device according to the present invention and further details of a process of fabricating such a semiconductor device in accordance with the present invention will be more clearly understood from the following description taken in conjunction with the accompanying drawings in which like reference numerals designate similar or corresponding elements, regions and portions and in which:  
       FIG. 1A-1  and  1 A- 2 ,  1 B,  1 C 1 D show a method and structure according to first example embodiment of the invention.  FIGS. 1A-1  and  1 A- 2  show the formation of the doped or implanted region  104  and the carbon-containing layer  112  according to an example embodiments of the invention.  
       FIG. 2A, 2B ,  2 C  2 C- 1 ,  2 D,  2 E and  2 F and  2 G show a method and structure according to example embodiment of the invention.  
       FIGS. 3A, 3B ,  3 C show a method and structure where the C-containing layer is in different positions/depths according to example embodiments of the invention.  
       FIG. 4A and 4B  show a second aspect of an embodiment, where the carbon containing layer  20  can be formed by an growth or deposition process.  
       FIGS. 5A, 5B ,  5 C  5 D,  5 E,  5 F,  5 G and  5 H show a method and structure for an example embodiment where the substrate structure comprises a strained layer.  
       FIGS. 6A, 6B ,  6 C and  6 D show a method and structure for an example embodiment wherein the carbon-containing layer diffuses up towards the surface and down towards the substrate center to create a “retrograded C-containing layer”  
       FIG. 7A  shows an example embodiment for a structure and method for forming implanted C-containing regions in a semiconductor device in the projected range and EOR ranges of implanted (doped or PAI) regions such as SDE, S/D, pocket implant regions.  
       FIGS. 7B-1 ,  7 B- 2  and  7 B- 3  illustrate in general, an aspect of the example embodiment where we form an implanted C-containing region and a EOR region within the doped region.  FIG. 7B-1  shows an implanted doped region and an EOR region.  FIG. 7B-2  shows a rough concentration profile on an implanted region.  FIG. 7B-3 , shows we form a C-containing layer about in the projected region and the EOR region.  
       FIGS. 8A   8 B and  8 C show an example embodiment where a C-containing layer is formed in the EOR of a pre-amorphization implant (PAI).  
       FIGS. 9A and 9B  are XTEM Images showing samples prepared after annealing at RTP 650° C. for 20 sec according to example embodiments.  FIG. 9A  has a C-containing layer that reduced defects.  
       FIG. 9C  illustrates the TOF-SIMS measurement performed on samples with and without the embodiments C-containing layer.  
       FIG. 9D  is an XTEM image that shows the presence of EOR dislocations in the sample without the incorporation of carbon.  
       FIG. 9E  is an XTEM image showing the absence of EOR defect band with the presence of the embodiment&#39;s substitutional carbon layer for 0.1% carbon incorporation subjected to spike annealing temperature of 1050° C.  
       FIG. 9F  shows SIMS measurements of indium ion for samples with and without the c-containing layer.  
       FIG. 9G , shows a graph comparing the junction leakage of a diode with and without the embodiment&#39;s carbon containing layer (Si 1-y C y ).  
       FIG. 9H  shows a graph of I leak  v V bias  for a FET with a carbon-containing layer and without.  
       FIG. 10  shows a typical implant doping profile at different implantation energies according to the prior art.  
    
    
     DETAILED DESCRIPTION OF THE EXAMPLE EMBODIMENTS  
      The present invention will be described in detail with reference to the accompanying drawings. The example embodiments of the present invention provide structures and methods of forming a device having a carbon (C) containing layer. The embodiments below are examples and can be modified. The invention is defined by the claims.  
     I. Overview of the Example Embodiments  
      Some major example embodiments comprise the following: 
      embodiment—FET with carbon-containing layer between the Rp of a first implanted region to the bottom of the EOR region of a second implanted region at a lower depth than said first implanted region (e.g.,  FIG. 1 -D).     embodiment—FET with carbon-containing layer (e.g.,  FIG. 2H ) 
        a) (first aspect) carbon-containing layer formed by ion implant (e.g.,  FIGS. 2A-2D )     b) (second aspect) carbon-containing layer formed by a growth process (e.g.,  FIGS. 4A-4B )    
        embodiment—FET with carbon-containing layer and Strained region (e.g.,  FIGS. 5E-5H ) 
        a) first aspect—strained region formed by growth or cvd process. (e.g.,  FIGS. 5A-5D )     b) second aspect—strained region formed by implant process. (e.g.,  FIG. 5E )    
        embodiment—C-containing layer that is diffuses during an anneal to form a retrograde C concentration profile C-containing layer (e.g.,  FIGS. 6A-6D )     embodiment—Implanted C-containing layers in the projected regions and EOR regions of implanted doped regions (E.g. S.D, SDE, Pocket regions). (e.g.,  FIG. 7A )     embodiment—C-layer in EOR Regions of PAI regions (e.g.,  FIG. 8C )    

      These non-limiting example embodiments are explained in more detail below. Additional major example embodiments are also described in the specification and claims.  
     II. Definitions and Abbreviations  
      The terms are defined and explained as follows: 
      c-layer—carbon containing layer     carbon layer—carbon containing layer     projected range (Rp) is the median depth of the implanted ions (before anneal).     EOR (end of range) region is a region typically below the Rp that contains defects from the ion implantation that creates an amorphous region. The location of the EOR region is highly depend on the implant process. An estimate of the region of the EOR defects location is the region between 1.0 Rp and 2.0 Rp, but does not have to extend totally between 1.0 Rp and 2.0 Rp. For larger implant species and at high doses of greater than 1E15 ions/sq-cm, the EOR range may extend from 1.5 Rp to 1.8 Rp or from 1.5 Rp to 2.0 Rp. The EOR region typically begins at the 1.0*Rp and extends down to a depth where most of the EOR defects are located (e.g., down to a depth of between 1.5 Rp to 2.0 Rp).    

      End of range region (EOR region) is the region in or under an implanted region that preferably contains 90% or more of the EOR defects.  
      In the figures, the EOR defects are drawn only outside the doped regions (e.g., source drain and halo regions) because the EOR defects when present outside and /or below these doped region causes severe leakage. If the EOR defects are in the doped region the leakage is considerable less. 
      End of range defects—are typically created by an implant that amorphrized the crystal (e.g., Si) structure. The EOR is typically below the crystal/amorphous interface in an implanted region.     Junction depth or depth of doped region—defined as depth from substrate surface where the n and p concentration are about equal. Schematically, the drawn junctions represent the boundary at which the n-type and p-type dopant are equal. These can be adjusted with adjusting the implant profiles either with different implant energy, dose and species type. In general, in the figures, the junction depth of the doped regions corresponds to a dopant concentration about 1E17 atom/cc.     SDE—source drain extension     PAI region—pre-amorphization implant region    

     III. Overview—General Example Embodiment  
      Some example embodiments form a carbon-containing layer in the EOR regions of an implanted (e.g.,) doped region in a silicon containing substrate. The carbon-containing layer and the implanted region can be formed in any order. The carbon-containing layer helps reduce defects from the implant that formed the implanted or doped region.  
       FIGS. 1A-1  and  1 A- 2  show the formation of the doped (can be active or non-active ion) or implanted region  104  and the carbon-containing layer  112 . These steps may be formed in any order.  
      Referring to  FIG. 1A-1 , a region  104  is formed by an implant process.  FIG. 1A-1  shows the depth of the projected range (Rp) or (1*Rp) of the implant and 2times the depth of the projected range (2*Rp).  
       FIG. 1A-2  shows a carbon-containing layer  112  in a substrate. The carbon-containing layer  112  is preferably formed at in at least the EOR region of the implanted region. The EOR region is estimated to be at about at depth between 1*Rp and 2.0*Rp of the subsequently formed doped region.  
      Preferably the substrate is a crystalline Si substrate. Preferably the substrate is comprised of silicon. In an example embodiment the substrate is comprised of a lower strained region and an upper silicon cap; the lower strain region is comprised of Si 1-y Ge y  or Si 1-y C y  where y is between 0.01 and 0.3. The substrate can be any substrate structure used in semiconductor manufacture , such as, but not limited to SOI substrates.  
      Preferably the C-containing layer has a concentration between 5E18 and 1E20 Atoms/cc.  
      Preferably the carbon containing layer is comprised of Si 1-y C y  alloy with y between about 0.001 and 0.005.  
      Preferably the C-containing layer is positioned at least in the EOR region of the doped region or regions(s). The doped regions can include the PAI, SDE, pocket, and/or S/D regions in any combination.  
      Preferably, the C-containing layer is positioned between the projected range of the doped region (Rp dr ) and 2.0 times the projected range of the doped region (2*R pd ). More preferably, the C-containing layer is positioned between the projected range of the doped region (Rp dr ) and 1.5 times the projected range of the doped region (1.5*Rp dr ).  
      Referring to  FIG. 1B , the doped region  104 , the end-of-range (EOR) defects  108 , and the carbon-containing layer are shown.  
      Referring to  FIG. 1C , the substrate is annealed and the end-of-range (EOR) defects  108  are reduce because of the carbon-containing layer.  
      The doped region and the carbon-containing layer are preferably annealed at a temperature between 625 and 900° C. and more preferably between 650 and 850° C.; and most preferably between 650 and 800° C. The anneal is preferably performed for a time between 1 and 60 seconds and more preferably between 10 and 30 seconds. The carbon containing layer  112  (Si 1-y C y ) getters defects and allows the lower anneal temperature. The C-layer will diffuse during the anneal and may diffuse up above 1.0 Rp and down below 1.5 Rp to about 2.0 Rp.  
      Preferably, the carbon-containing layer is not positioned in a channel region of an FET.  
      A. C-containing Layer Between Two Implanted Regions  
      The C-containing layer can extend over and between the EOR regions two or more implanted regions. For example, referring to  FIG. 1D , a first region  104  and a second region  105  are implanted in a substrate  100 . A carbon-containing layer  112  is formed that extends from the top of the shallower EOR region (e.g., second region 105—the Rp of second region) to about the bottom of the lower EOR region (e.g., first region  104 —1.5*Rp-1 st  region). The implanted regions and carbon-containing layer can be formed in any order.  FIG. 1D  is shown post anneal.  
      As a further example, the first region could be a source/drain region and the second region could be a pre-amorphization region (PAI region), pocket or SDE region. The regions are shown is a simplified layout only for illustration and can be configured/positioned differently in a device.  
      The following are non-limiting examples of the location of carbon-containing layer in different aspects of the embodiment: 
      aspect—carbon-containing layer only extends from Rp-PAI to 1.5 Rp SD     aspect—c-layer extends only between Rp-SDE and 1.5*Rp SD     aspect—c-layer only extends between Rp-pocket and 1.5*Rp SD     aspect—c-layer only extends between Rp-SD and 1.5*Rp SD     aspect—c-layer only extends between Rp-SD and 1.5*Rp SD     aspect—carbon-containing layer only extends between 1 Rp-PAI to 1.5*Rp-PAI     aspect—carbon-containing layer only extends between 1 Rp-SDE to 1.5*Rp-SDE     aspect—carbon-containing layer only extends between 1 Rp-pocket to 1.5*Rp-pocket     aspect—carbon-containing layer only extends between 1 Rp-SD to 1.5*Rp-SD    

     IV. Embodiment—First Aspect-FET with C-containing Layer—e.g., FIGS.  2 A- 2 H  
      A main feature of the aspect shown in  FIG. 2H  is that preferably a carbon containing layer  20  (Si 1-y C y ) extends at least from the projected range of the SDE (Rp-SDE or RP SDE ) through to the bottom of the source/drain end-of-range (EOR) region (e.g., 1.5 to 2.0 times Rp SD ).  
      The dopant end of range (EOR) region is typically found at a depth at least between about 1 to 1.5 times the Rp implanted species and more preferably between found at a depth between about 1 to 1.8 times the Rp implanted species and could be found at a depth between about 1 to 2.0 times the Rp implanted species.  
      In a first aspect of the embodiment, the carbon containing layer  20  can be formed by an implant process. (See e.g.,  FIGS. 2A  to  2 D).  
      In a second aspect of the embodiment, the carbon containing layer  20  can be formed by an growth or deposition process. (See e.g.,  FIGS. 4A  to  4 B) The carbon containing layer  20  (Si 1-y C y ) getters defects from the SDE, pocket and S/D implants. The carbon containing layer  20  (Si 1-y C y ) is preferably not in the channel region.  
      The post S/D formation anneal, is preferably performed at a low temperature below 800° C. and preferably between 650 and 850° C. for between 5 seconds and 10 minutes. The carbon containing layer  20  (Si 1-y C y ) getters defects and allows the lower anneal temperature.  
      A. First Aspect of the Example Embodiment—Carbon Containing Layer can be Formed by an Implant Process  
      Forming a Carbon Containing Layer  20  in a Substrate  
      Referring to  FIG. 2A , a substrate  10  that has an upper crystalline silicon surface is shown.  
      The substrate may be a substrate employed within a microelectronics fabrication. Although not specifically illustrated within the schematic cross-sectional diagram of  FIG. 1A , the substrate  10  may be the substrate itself employed within the microelectronics fabrication, or in the alternative, the substrate may be the substrate employed within tile microelectronics fabrication, where the substrate has formed thereupon or thereover any of several additional microelectronics layers as are conventionally employed within the microelectronics fabrication.  
      The substrate is preferably a silicon wafer. The substrate may further comprise wells.  
      Implantation to form a C-containing Layer  
      As shown in  FIG. 2B , a carbon containing layer  20  is formed by implanting carbon ions into the substrate.  
      Preferably the carbon layer  20  overlaps with the EOR of the a subsequent (dopant) implanted region. The carbon dose is preferably between 7.5 E 18atoms/sq-cm and 1E20 atoms/sq-cm. The carbon implant can be either an amorphous or non-amorphous implant, and is preferably a non-amorphous implant.  
      As shown in  FIG. 2C , the preferably the carbon implant projected range (Rp) overlaps the entire EOR of the dopant region (s) that we are using the c-layer to getter defects. Preferably the carbon layer Rp (Rp c ) is extents to depths between about 1 Rp-dopant to 2 times Rp-dopant (2*RP dopant ) and about preferably extends between 1.0 and 1.8 Rp-dopant and most preferably between 1.0 and 1.5 Rp-dopant.  
      As shown in  FIG. 2C-1 , the carbon layer preferably has a thickness (where the C concentration is greater than about 5E18 atom/cc) relative to the dopant region of between about 1.0 Rp dopant  to 2.0 Rp dopant . The Rp-carbon can preferably be between 0.9 and 1.6 Rp-dopant and more preferably of about between 1.0 and 1.5 Rp-dopant.  
      For example, the dopant can be the, PAI region (e.g., C or Si implant ions), SDE (source-drain extensions), the pocket region, and/or the source/drain regions.  
      The substrate and C-containing layer is preferably annealed after the dopant implant, such as after the source/drain implant.  
      The carbon containing layer  20  can be comprised of Si y C 1-y . The carbon containing layer  20  is preferably comprised of Si y C 1-y  alloy and preferably has a concentration with y between about 0.001 and 0.005.  
      The carbon containing layer  20  is preferably comprised of Si y C 1-y  alloy and preferably has a C concentration of between 5E18 and 1E20 atoms/cc and more preferably of between 1E19 and 2E19 atoms/cc.  
       FIG. 2E  shows the carbon-containing layer  20  at a depth below the substrate  10  surface with a region  30 A of silicon-containing region above the carbon-containing layer  20 .  
      Form A Gate Structure  
      Referring to  FIG. 2E , we form a gate structure  40  over the substrate  10 . A channel region  42  is in the substrate  10  under the gate structure.  
      The gate structure is preferably comprised of a gate dielectric  34 , a gate electrode  36  and first gate spacers  38 .  
      Implanting Ions To Form A Pocket Region  
      Referring to  FIG. 2F , we implant ions to form a pocket region  44 , a pocket EOR region and pocket EOR interstitials  45  in the pocket EOR region.  
      The pocket regions  44  is at least partially in the carbon containing layer  20 . The pocket region  44  has the opposite impurity type as the SDE and S/D regions. The pocket regions  44  preferably has about the same concentration as the substrate or well and channel region.  
      The depth for the pocket region  44  and the pocket EOR region depends on the technology node of the device being formed.  
      Form S/D Extension Regions  
      As shown in  FIG. 2F , we form source drain extension regions (S/D extension regions  50 , SDE ) in the substrate adjacent the gate structure.  
      The SDE regions preferably have a depth between 10 and 50 nm and a concentration between 1E19 and 1E21 atom/cc.  
      The SDE implant also forms EOR defects (not shown) in a SDE EOR region.  
      Forming S/D Spacers  
      As shown in  FIG. 2G , we form S/D spacers  52  on the sidewalls of the gate structure  40 . The S/D spacers  52  can be formed over existing spacers  28 .  
      Forming Source/Drain Regions  
      As shown in  FIG. 2G , we form source/drain regions  54  in the substrate adjacent the gate structure. Schematically, the drawn junctions represent the boundary at which the n-type and p-type dopant are equal. These can be adjusted with adjusting the implant profiles either with different implant energy, dose and species type.  
      The source/drain regions  54  formed by an ion implant process where preferably the S/D EOR region are in the C-containing layer  20 .  
      The region between about Rp and 1.5 Rp is an estimate of the region of the EOR defects location. For larger implant species and at high doses of &gt;1E15 the EOR may extend from 1.5 Rp to 1.8 Rp. In the figures, the EOR defects are drawn only outside the source drain and halo region because the defects when present in these region causes much severe leakage compared to if the defect is present in the source-drain region itself.  
      Position Of The C-containing Layer  
      Preferably the dopant regions and carbon-containing layer are positioned so that the carbon containing layer extends between the Rp SDE  to the bottom of the S/D EOR region (e.g., 2.0*Rp SD ). Substantially all of the channel region is preferably not the carbon containing layer.  
      The depths of the source/drain regions  54 , source/drain projected range source/drain EOR regions depend on the technology.  
      The projected range and end-or-range regions for the SDE regions, pocket implant region, and the source/drain implant regions are preferably in the carbon containing layer.  
      In other aspects of the embodiment, any combination of the projected range and end-or-range regions for the (a) PAI regions (b) SDE regions, (c) pocket implant region, and (d) the source/drain implant regions are in the carbon containing layer.  
      Annealing the Substrate  
      Still referring to  FIG. 2H , we preferably anneal the substrate (in a post S/D anneal) whereby the carbon containing layer acts as a sink for defects (e.g., interstitials) from the pocket implant, and source/drain implant.  
      The c-layer anneal performed at a temperature between 650 and 850degree C. and for a time between 1 and 60 seconds and more preferably between 10 and 30 seconds. Preferably this C-containing layer anneal is the higher temperature anneal the device is subjected to.  
      Depending on the technology, there may be anneals before the post S/D anneal, such as post SDE.  
      The carbon containing layer  20  (Si 1-y C y ) getters defects from the SDE, pocket and S/D implants. The carbon containing layer  20  (Si 1-y C y ) is preferably not in the channel region. The channel region depth is a function of the device and technology and varies with the electric field. Currently, the channel region has a depth of from about 3 Å to about 10 Å.  
      B. Example Positions of the Carbon Containing Layer  
       FIG. 3A  shows an aspect where the SDE EOR region is in the c-layer.  
       FIG. 3B  shows an aspect where the pocket EOR region is in the c-layer.  
       FIG. 3C  shows an aspect where the SD EOR region is in the C-containing layer.  
      Other combinations of aspects are possible.  
     V. Second Aspect of Example Embodiment—C-containing Layer Formed by a Growth Process  
      In a second aspect for forming the carbon-containing layer, a growth process is used to form the carbon-containing layer.  
      Referring to  FIG. 4A , we form a carbon containing layer  20  over or on a substrate  10 .  
      The carbon containing layer  20  can be formed by a growth method such as chemical vapor deposition or epitaxy growth. Most preferably the carbon containing layer  20  comprised of Si y C 1-y  is formed by a epitaxial growth process. The carbon containing layer  20  preferably has parameters (e.g., thickness, concentration) as described above.  
      Referring to  FIG. 4B , we form a silicon layer  30  (or silicon containing layer) over or on the carbon containing layer  20 .  
      The silicon layer  30  is preferably comprised of a silicon epitaxy layer formed by an epitaxy process. The silicon layer is preferably a crystalline Si.  
      For a given technology, the silicon layer  30  (e.g., silicon cap layer) preferably has a thickness between 200 and 500 Å.  
      The silicon layer  30  preferably has a thickness about 0.5*thickness of the gate oxide+(1-1.5*Rp SDE ). For example if t ox  (Thickness of gate oxide)=20 Å, RP SDE =20 nm then T Sicap =31 nm.  
      The process continues as explained above in the first aspect and shown in  FIGS. 2E  thru  2 G.  
     VI. Example Embodiment—Substrate Structure Further Comprises a Strained Region  
      In a example embodiment, shown in  FIGS. 5A  to  5 H, the substrate structure includes a strained layer. The structure is preferably comprised of a lower strained region ( 110 ) and overlying upper (unstrained) silicon cap  116 . The lower strain region  110  is preferably comprised of Si 1-y Ge y  or Si 1-y C y  where y is between 0.001 and 0.0003.  
      In a first aspect, the strained region is formed by growth or chemical vapor deposition process. (e.g.,  FIG. 5A  to  5 H)  
      In a second aspect, the strained region is formed by implant process.  
      The embodiment is discussed in more detail below.  
      A. First Aspect—Grown Strained Layer  
      In the first aspect of the embodiment, as shown  FIGS. 5A  to  5 D,  5 E to  5 H, substrate structure is comprised of a substrate  10 , a lower strained region  110  and a upper silicon cap  116 .  
      Referring to  FIG. 5A , a substrate  10  is shown.  
      Referring to  FIG. 5B , a strained region  110  is formed over the substrate  10 . The strained inducing material is preferably grown on the substrate to a thickness sufficient to induce strain in silicon i.e., Si 1-x Ge x , or Si 1-x C x where x is between about 1 and 30% and more preferably x is between about 1 and 10%.  
      Referring to  FIG. 5C , a carbon containing layer  120  is formed over the strained region  110 . The carbon containing layer is preferably deposited or grown along with the strained region whose intended position is dependent on the implantations of the S/D SDE.  
      Referring to  FIG. 5D , an optional silicon layer  116  is formed over the carbon containing layer  120 . The silicon layer is preferably comprised of silicon, but can have other elements. The carbon containing layer is comprised of a upper silicon layer  116  and a lower carbon containing layer  120 . Preferably in this technology, the silicon (containing) layer  116  has a thickness between 0 and 100 Å and more preferably between 5 and 100 Å. The silicon layer is preferably not strained. The desired channel location and stress/strain can determine thickness of the silicon layer. For example, for a compressive strain channel, for a Si 1-y Ge y  strained region  110 , a Si-layer is not formed. For example, for a compressive strain channel, for a Si 1-y C y  strained region  110 , a Si-layer preferably has a thickness between 60 and 100 Å.  
      For example, for a tensile strain channel, for a Si 1-y Ge y  strained region  110 , a Si-layer preferably has a thickness between 60 and 100 Å. For example, for a tensile strain channel, for a Si 1-y C y  strained region  110 , a Si-layer is not formed.  
      B. Second Aspect—Strained Region is Formed by Implant Process.  
      In a second aspect, the strained region is formed by an implant process. For example, Ge or C ions can be implanted into the substrate. The process continues as discussed below. For example, referring to  FIG. 5D , a strained layer  110  formed by an implanted. Also referring to  FIG. 5D , the C-containing layer  120  can also be a strained layer.  
      C. Steps to from Device— FIGS. 5E  to  5 H  
      Referring to  FIG. 5E , processes are performed to form a structure preferably has a carbon containing region  120  (carbon rich region) and strain region  110 , a silicon cap  116 , a gate dielectric  34 , a gate electrode  36  and gate spacers  38 .  
      The carbon containing region  120  and the strained region  110  are preferably formed using an epitaxy process and more preferably a RPCVD process.  
      The strained region  110  is preferably comprised of Si 1-x Ge x  or Si 1-x C x  where x is between about 1 and 30% and more preferably x is between about 1 and 10% and preferably has thickness of about 1 μm (0.8 to 1.2 μm) to induce strain in the channel.  
      Referring to  FIG. 5F , a pocket implant is performed to form a pocket region  44 . A pocket end-of-range (EOR) region and pocket interstitials  45  are undesirably formed.  
      Referring to  FIG. 5G , spacers  52  are formed over the gate structure sidewalls. The spacers  52  can be formed over the (first) spaces  38 .  
      Next, source/drains  54  are formed by a S/D implant. S/D interstitials  55  are undesirably formed in a S/D end-of-range (EOR) region.  
      Referring to  FIG. 5H , the structure is annealed where preferably the interstitials are removed.  
      The carbon rich layer  120  preferably extents between (a) 1 to 1.5 Rp SDE  and 1.0 to 2.0 Rp S/D .  
     VII. Embodiment—“Retrograded C-containing Layer” 
      In another example embodiment, a “thin” C-containing layer is formed in a substrate. When the thin C-containing layer is anneal, the carbon-containing layer diffuses up towards the surface and down towards the substrate center to create a “retrograded C-containing layer”. This reduces the C in or near the channel region of the FET.  
      Referring to  FIG. 6A , the thin C-containing layer  220  is formed in or on a substrate  220 . The C-containing layer  220  is preferably formed by an epitaxy process.  
      As shown in  FIG. 6B , a silicon layer  230  is formed on or over the thin C-containing layer  220 . The “thin” C-containing layer  220  (no anneal) preferably has a thickness between ˜30 and 60 nm. The carbon-containing layer (before anneal) preferably has a concentration between 1E19 and 1E20 atom/cc.  
      As shown in  FIG. 6C , we anneal the thin C-containing layer  220  to form a retrograde C-containing layer  220 A. The retrograde retrograde C-containing layer  220 A has outdiffusions  220 C and center part  220 B. The thin C-containing layer preferably is formed in the substrate in the subsequently formed EOR region of the source/drain region.  
      The carbon-containing layer (after anneal) preferably has a concentration between 1E18 and 1E20 atom/cc. The carbon-containing layer concentration is reduced after anneal because the C diffuses during the anneal. The carbon-containing layer  220 A (after anneal) preferably extends at least between Rp SDE  and 1.8*Rp S/D    
       FIG. 6D  shows a FET device formed on a substrate. Referring to  FIG. 6E , the following are formed: gate structure, SDE, pocket region, S/D regions. The retrograde C-containing layer  220 A is shown after the anneal. The retrograde C-containing layer  220 A preferably extends from the Rp of the S/D region to 1.5 Rp of the S/D region.  
      The C concentration on the top and bottom regions is preferably between 1E18 and 1E 19 and the C concentration in the center of the region 1E19 to 1E20 atoms/cc.  
      Preferably the retrograde C-containing layer  220 A is deep in the substrate away from the channel region and preferably in the EOR region of the source/drain region.  
      The carbon in the carbon containing layer diffuses up into the Si layer  30  and down into the substrate during subsequent heat processes thereby the carbon contain layer has a retro grade profile. During subsequent thermal processing steps, the carbon layer diffuses both way, both upward towards the surface of the silicon and deeper into the silicon substrate. The upward diffusion of the carbon impurity would cause graded profile where high concentration is obtained at the region where carbon is grown and its concentration decreases towards the silicon surface, decreasing the occurrence of accumulation of carbon species at the channel region.  
      In another embodiment, preferably the retrograde carbon containing region extends between the Rp-SDE and the bottom of the S/D EOR region (e.g., 1.5 to 2.0*Rp-SD).  
     VIII. Embodiment—Method for Forming an Implanted C-regions in EOR Regions  
      A. Overview  
      Referring to  FIG. 7A , in an example embodiment, a structure and method are described for forming implanted C-containing regions in a semiconductor device in the projected range and EOR ranges of implanted (doped or PAI) regions such as SDE, S/D, pocket implant regions.  
      As shown in  FIGS. 7B-1 ,  7 B- 2  and  7 B- 3 , in general, an aspect is that we form an implanted C-containing region and a EOR region within the doped region.  
       FIG. 7B-1  shows an implanted doped region and an EOR region.  
       FIG. 7B-2  shows a rough concentration profile on an implanted region. The EOR region usually is present at a depth between 1 Rp and 1.8 Rp or more usually between about 1 Rp and 1.5 Rp.  
      As shown in  FIG. 7B-3 , we form a C-containing layer about in the projected region and the EOR region. The C-containing layer is preferably formed by an implant process. The C-containing layer getters defects from the doped region and EOR region. The carbon-containing layer extends from between a depth 1.0 Rp dopant  and 2.0*Rp dopant. The carbon-containing layer preferably has a concentration above 5E 18 atoms/cc from between a depth at the Rp dopant  and 2.0 Rp dopant .  
      The carbon-containing layer more preferably has a concentration between 5E 18 and 1E20 atoms/cc from between a depth at the RP dopant  and 2.0 Rp dopant. The carbon-containing layer preferably as a Rp C containing-layer  located between Rp dopant  and 1.5 Rp dopant .  
      For the embodiment, the parameters for the C-implant and C-containing layers are as described above unless otherwise noted.  
      B. Form a Gate Structure  
      Referring to  FIG. 7A , we provide a substrate  300 . The substrate is preferably a pure semiconductor material(s) such as a Si wafer or a Si/Si strained Si structure.  
      We form a gate structure  340  over the substrate. A channel region  342  is in the substrate under the gate structure.  
      C. Form a Pocket Region and a Pocket EOR Region  
      We implant ions to form a pocket region  344 , pocket projected range region and a pocket EOR region (not shown but roughly located in the carbon-containing pocket EOR layer  345  ) in the substrate.  
      The pocket implant process can comprise As, B, BF 2 +.P or P ions at a dose between 1E13 and 1E14 ions/sq-cm, at an energy sufficient to located the pocket implant region below the SDE but shallower than the S/D region.  
      D. Form a Carbon-containing Pocket EOR Region  
      We implant C ions preferably at least into the pocket EOR regions to form a carbon-containing pocket EOR region  345 . The Rp of the C-containing pocket region is preferably between 1*Rp pocket  and 2*RP pocket  and more preferably between 1*RP pocket  and 1.5 RP pocket .  
      The carbon-containing pocket EOR region  345  preferably a carbon concentration between 5E18 and 1E20 atom/cc.  
      For example, for a B pocket implant of 1E15/sq-cm at 30 Kev, an example of the C-implant process parameters are: 7E13 ions/sq-cm at between 35-40 KeV at same twist and tilt angle as the pocket implant.  
      In general, the implants of the doped regions and carbon-containing regions can be performed in any order. For example, the C-containing regions  345  can be implanted before the pocket region  344 .  
      E. Form SDE Regions and SDE EOR Regions  
      We form SDE regions  350  and SDE EOR regions preferably using an implant process in the substrate adjacent the gate structure. The implant process for the SDE&#39;s can form EOR regions where EOR defects are formed in the crystal lattice.  
      F. Implant C Ions into the Substrate in the SDE EOR Region to form Carbon-containing SDE EOR Regions  351   
      Then we implanting C ions into the substrate in the SDE EOR region to form carbon-containing SDE EOR regions  351 . The preferred parameters for the C-containing layer and the C-implant are described above.  
      For example, for an As SDE implant of: implant angle of 7 degrees, 22 degree twist, 2 keV, 1.5E15 dose and An example of the C-implant process parameters are: C does 7E13 atoms/sq-cm at 2 KeV with similar twist and tilt as SDE.  
      G. Form S/D Spacers  
      We form S/D spacers  352  on the sidewalls of the gate structure  340 .  
      H. Form Source/Drain Regions and Source/Drain EOR Regions  
      We form source/drain regions  354  and source/drain EOR regions  355  adjacent the gate structure.  
      The source/drain regions  354  are preferably formed by an ion implant process. The channel region is preferably not in any carbon containing layer.  
      I. Form Carbon-containing Source/Drain EOR Regions  
      We implant C ions into the substrate in the source/drain EOR regions to form carbon-containing source/drain EOR regions  355 .  
      The carbon-containing source/drain EOR regions  355  preferably have a carbon concentration between 5E18 and 1E20 atom/cc, and a thickness related to the Rp dopant  as described above.  
      An example of the C-implant process parameters are: 7 degree angle, 22 degree twist, 10-50 KeV energy, and 1E14 atoms/sq-cm dose.  
      J. Anneal  
      We preferably anneal the substrate whereby the carbon containing layers act as a sink for defects (interstitials) from the pocket implant, the SDE implant and source/drain implant.  
      Preferably the end-or-range regions for the pocket implant, the SDE implant and the source/drain implant are in the carbon containing layers.  
      The anneal is preferably performed at a temperature between 650 and 899 degree C. and for a time between 1 and 60 seconds and more preferably between 10 and 30 seconds. More preferably, the anneal is performed at a temperature between 650 and 850 degree C. and for a time between 1 and 60 seconds and more preferably between 10 and 30 seconds. This anneal has a lower temperature than a standard anneal. A standard anneal is performed at a T between 900 and 1100 degree C.  
      An example of the preferred order of implants is: carbon-containing pocket EOR region  345 , pocket region  344 , C-layer  351 , SDE  350 , C-layer  355 , and S/D regions  354 . However, the implants can be performed in other orders.  
     IX. Example Embodiment—C-containing Layer in EOR of PAI Implants  
      In an example embodiment, a C-containing layer is formed in the EOR of a pre-amorphization implant (PAI). See, for example,  FIGS. 8A  thru  8 C.  
      Amorphous layers created using non-dopant implants are used in conjunction with shallow implants to reduce channeling and to affect TED and dopant activation. To prevent the channeling of boron implant, a Ge implantation is introduced prior to Boron implantation followed by an annealing process which conditions are just sufficient for solid phase epitaxy regrowth (SPEG) of the silicon crystal, typically at 600-800 C for several seconds. The annealing condition is good as it provides high activation and minimized boron diffusion in the silicon substrate. However, the implantation of Ge by itself introduces massive EOR defects at the tail end of PAI implantation region which leads to leakage current in the MOSFET.  
      In this embodiment, a layer of carbon rich region is placed at the PAI implant profile region and subsequently annealed at SPEG conditions. It is possible to eliminate the EOR defects which are typically associated with the low temperate annealing of &lt;900° C.  
      Boron which is a small dopant species experiences channeling phenomena when implanted into the silicon lattice. This would result in the boron dopant landing in a projected depth of up to 4 times its intended projected range, a phenomena which is undesirable for the compliance to the Ultra-shallow junction roadmap. Boron implant is often performed at doses of &gt;1E15 and energy of &lt;1 keV.  
      An approach to PAI is as follows. Prior to the B implant, a pre-amorphization implant (PAI) step is performed to induce amorphization to the crystalline substrate to induce disorder. The prevents the B channeling phenomenon. PAI implants are currently typically performed for p-type regions, but PAI implant could be used also.  
      One problem associated is the annealing at low temperatures for boron activation after the implantations in a CMOS fabrication process. The EOR defects resulted from the aggressive PAI implant (typically with Ge species of 5-10 keV at doses &gt;1E15) results in high density of residual EOR defects after anneal. The presence of these defects results in high leakage current when present in the reverse biased PN junction.  
      A. Form C-containing Layer in PAI EOR Region  
      Referring to  FIG. 8A , a gate structure  840  is formed on a substrate  800 . A PAI implant is performed to form a PAI region  860  and PAI EOR defects  865 .  
      Referring to  FIG. 8B , a carbon-containing layer  820  is (e.g., implanted) formed with preferably with a concentration preferably less than 0.5% at a depth preferably between 1.5 and 2.0 Rp of the PAI implanted region. In a preferred embodiment the carbon-containing layer  820  extends between a depth of 1.5 and 2.0 Rp of the PAI implanted region.  
      Referring to  FIG. 8C , a SDE implant is performed to form SDE regions  850 . Preferably P-type (e.g., boron) dopants are implanted.  
      Referring to  FIG. 8C , an SDE anneal is performed preferably at a temperature less than 950° C. The residual defects that are typically formed are eliminated due to the carbon-containing layer.  
     X. Example Benefits Related to Some Example Embodiments  
      A. High Temperature Anneals of Implant Damage have Undesirable Effects  
      An annealing process is typically performed after implantation at significantly high temperatures to remove the implantation induced damage from the silicon. Three considerations for annealing of the implantation damage are as follows.  
      1) Reconstruction of the Crystalline Lattice due to Amorphization  
      This process involves a solid phase epitaxy process (SPE), requiring the reconstruction of the silicon crystalline lattice and occurs at temperature ranging from 500 to 800° C. and above. The growth rate of the amorphous layer is strongly dependent on the temperature, with higher growth rate for higher annealing temperatures.  
      2) Removal of Defects  
      During SPE, clustering of silicon interstitials at the end-of-range (EOR) region causes the formation of secondary defects (eg. Dislocation planes and defect loops). These defects when present in the depletion region of the pn junction cause severe leakage current to the junction and must be removed. However, the removal of these defects require high activation energy (Ea ˜5 eV) requiring HIGH TEMPERATURES (Typically &gt;950° C.) processing conditions.  
      3) Activation of the Dopants  
      Implanted dopants into the silicon substrate occupy interstitial sites and must be activated before it can function as acceptors or donor ions in silicon. The activation of dopant ions involves placing or moving the dopants located at the interstitial sites back into the substitutional sites in silicon. Generally, the higher the annealing temperature, the higher the activation. However, a large percentage of the implanted dopant ions are activated during the SPE process, where the dopants are incorporated to the substitutional silicon sites along with the re-crystallization growth of the silicon lattice.  
      The problem with the annealing of ion implantation induced damage is that they require very extreme temperature processing conditions with typically Rapid Thermal Anneal (RTA) of&gt;1000° C. for times of 30-60s for effective annealing, usually the highest temperature in the fabrication process. Such high temperature processing conditions causes dopant diffusion which is undesirable and difficult to control for the continuous scaling of the MOSFET into the nano-meter channel length regime. Also the loss in the desired strain in the strained silicon substrate.  
     B. Example Embodiments  
      By means of the introduction of a layer of carbon rich region, some of the embodiments of the invention can eliminate the problem associated with problem 2—Removal of Defects.  
      Carbon species when present in the silicon lattice can act as sink for interstitials. By incorporating carbon into silicon, the carbon can reduce the presence of EOR defects. Also, the activation energy for carbon to perform as silicon sinks is in the range of 2.5 to 3 eV. This is about similar activation energy for the regrowth of amorphization layers. Hence, there is an indication of possibility of the reduction in thermal budget. This would reduce the required annealing temperature condition, reducing the overall thermal budget of the MOSFET device fabrication process.  
      Carbon which performs as silicon interstitial sinks, prevents the enhanced dopant diffusion (e.g., Phosphorus, Boron and Indium), whose mode of enhanced diffusion is dependent on the concentration of silicon interstitials present in the region. The C-containing layer can have the following advantages: 
      1) Facilitation of Ultra-Shallow Junction formation     2) Better control of transistor short channel effect (SCE) and reverse short channel effect (RSCE) as lower temperature processing condition decreases dopant diffusion in the channel region of the MOSFET.     3) Retention of the desired strain in strained silicon technology.    

     XI. Examples  
      A. Experimentrl Results on Annealing of Samples Implanted with Heavy Indium Dose (1×10 14  cm −2 )→as Source Drain Implantation (SDE)  
      An Indium implant marker was used as an indicator of the presence of EOR defects, as indium ions behaves to segregate into EOR dislocation loops during annealing. The HEAVY INDIUM (In) DOSE was about 1×10 14  cm −2    
      The As Source Drain Implantation was at dose of 1.5 E15 and an energy of 2 Kev.  
      Embodiment&#39;s Carbon Containing Layer Reduces Defects with Low T Anneal  
       FIGS. 9A and 9B  are XTEM Images showing samples prepared after annealing at RTP 650° C. for 20 sec.  
       FIG. 9A —(a.) shows substantial elimination of the EOR defect band with the presence of ˜0.5% of substitutional carbon grown specifically at the implantation EOR range region in the silicon substrate.  
       FIG. 9B —(b.) sample annealed without presence of carbon. The EOR defect band is clearly visible. For both images, no visible defect band was found corresponding to the SDE implantation.  
      Referring to  FIG. 9C , the TOF-SIMS measurement performed on the indium ion showed subtle segregation of indium into EOR peaks at the given annealing conditions is sample without carbon incorporation, indicating the presence of defects.  
      Embodiment&#39;s Carbon Containing Layer Reduces Defects with Higher T Anneal  
      At substantially even higher annealing conditions, no indication of EOR loops was observed.  FIGS. 9D and 9E , are XTEM images.  
       FIG. 9D  shows the presence of EOR dislocations without the incorporation of carbon.  
       FIG. 9E  shows the absence of EOR defect band with the presence of the embodiment&#39;s substitutional carbon layer for 0.1% carbon incorporation subjected to spike annealing temperature of 1050° C.  
       FIG. 9F  shows SIMS measurements performed on the indium ion for samples with and without the c-containing layer.  
      The two experimental results suggest with the presence of carbon; the absence of clustering of silicon interstitials for EOR defect formation is achieved through the entire annealing process, indicating no need for the typical high temperature annealing step.  
      There is also no defect corresponding to the low energy implantation caused by the SD implant. This is possibly due to the surface enhancement effect where the silicon surface is an effective sink for silicon interstitials, preventing EOR dislocation loops from being formed.  
     ELECTRICAL DATA  
       FIG. 9G , shows a graph comparing the junction leakage of a diode with and without the embodiment&#39;s carbon containing layer (Si 1-y C y ). The embodiments C-containing layer with an anneal in the range of 700° to 900°, has significantly lower junction leakage than the other processes.  
       FIG. 9H  shows a graph of I leak  v V bias  for a FET with a carbon-containing layer and without. The graph shows the embodiment&#39;s carbon-containing layer significantly improves leakage.  
     XII. NON-LIMITING EMBODIMENTS  
      In the above description numerous specific details are set forth such as flow rates, pressure settings, thicknesses, etc., in order to provide a more thorough understanding of the present invention. It will be obvious, however, to one skilled in the art that the present invention may be practiced without these details. In other instances, well known process have not been described in detail in order to not unnecessarily obscure the present invention.  
      Given the variety of embodiments of the present invention, the above description and illustrations should not be taken as limiting the scope of the present invention defined by the claims.  
      While the invention has been particularly shown and described with reference to the preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made without departing from the spirit and scope of the invention. It is intended to cover various modifications and similar arrangements and procedures, and the scope of the appended claims therefore should be accorded the broadest interpretation so as to encompass all such modifications and similar arrangements and procedures.