Abstract:
A new method is established to form different silicide layers over the top of the gate electrode and the surface of the source/drain regions. A thin layer of TiSi 2  is formed over the source/drain regions by depositing a layer of titanium and annealing this layer with the silicon substrate. The gate electrode is created as a recessed electrode, in the top recession of the electrode a layer of CoSi 2  is formed by depositing a layer of cobalt over the gate electrode. This layer of COSi 2  serves as the electrical gate contact point.

Description:
BACKGROUND OF THE INVENTION 
     (1) Field of the Invention 
     The invention relates to the fabrication of integrated circuit devices, and more particularly, to a process for a FET with TiSi 2  S/D contacts and CoSi x  gate contacts. 
     (2) Description of the Prior Art 
     Field Effect Transistors (FET&#39;s) have found wide application in the semiconductor industry. The fabrication of a FET typically starts with a single crystal semiconductor substrate; a thin layer of gate oxide is grown over the surface of the substrate. A polysilicon gate is patterned over the thin layer of gate oxide, the gate electrode is then used as a diffusion or implant barrier mask to form self-aligned source and drain areas in the substrate immediately adjacent to the sides of the gate electrode. The region between the source/drain regions is called the channel region, the distance between the source and the drain junction is called the channel length. In its simplest terms of operation, an input voltage is applied to the gate electrode, this voltage establishes an electric field in the channel region of the device, and this electric field is perpendicular to the surface of the substrate and the thin layer of gate oxide. By varying the value of the applied voltage, the conductance of the channel region can be controlled. Because the electric field that is established by this voltage controls the output current flow through the device, the semiconductor devices created using this approach are called Field Effect Transistors (FET&#39;s). 
     In a typical FET, metal contacts are established with the gate electrode and with the source and the drain regions of the transistor. This can be done by sputtering a layer of refractory metal over the exposed surface of these areas. By heating this layer of metal (typically titanium, tantalum, platinum, nickel or cobalt) to a temperature of between 200 and 850 degrees C., a self-aligned salicide region is formed on top of the gate electrode and on the source and drain regions. 
     Prior to the deposition of the above indicated layer of metal, contact holes to the source/drain regions have to be opened through the thin layer of gate oxide. As transistor dimensions have decreased, the conventional contact structures began to limit device performance. It was, for instance, not possible to minimize the contact resistance if the contact hole was of minimum size while problems with cleaning small contact holes became a concern. In addition, the area of the source/drain regions could not be minimized because the contact hole had been aligned to this region using a separate masking step whereby extra area had to be allocated to accommodate misalignment. It was also practice to use several, small contact holes of identical size meaning that the full width of the source/drain region was not available for the contact structure. This resulted in the source/drain resistance being proportionally larger than it would have been in a device having minimum width. 
     Self-alignment is a technique in which multiple regions on the wafer are formed using a single mask, thereby eliminating the alignment tolerances that are required by additional masks. As circuit sizes decrease, this approach finds more application. One of the areas where the technique of self-alignment was used at a very early stage was the self-aligned source and gate implant to the poly gate. 
     One of the alternate structures that have been employed in an effort to alleviate the problem of increased source/drain resistance is the formation of self-aligned silicides on the source/drain regions. Where these silicides are formed at the same time as the polycide structure, this approach is referred to as a salicide process. The entire source/drain region (of, for instance, a MOSFET device) is contacted with a conductor film. This approach becomes even more attractive where such a film can be formed using a self-aligned process that does not entail any masking steps. 
     Continuous shrinkage of the gate length demands low resistivity of the source/drain regions, as well as shallow junctions in the source/drain areas to avoid short channel effect, which is mainly caused by inappropriate dopant distribution underneath the channel region. Shallow junctions greatly help resolve this problem. 
     Various techniques have been developed for forming the shallow source/drain junctions that are needed for sub-micron CMOS devices. One such approach uses As for the n-channel devices while BF 2   +  is used for the p-channel devices. Yet another approach uses the creation of so-called elevated source-drain. A thin (for instance 0.2 um.) epitaxial layer of silicon can be selectively deposited onto the exposed source/drain areas of the MOS transistor, this following the implantation of the lightly doped region of the LDD structure and the formation of the spacers. This process leads to the formation of heavily doped, shallow source/drain regions. The source/drain junction depths in this case are less than 0.2 um. 
     FIG. 1 shows Prior Art formation of a gate electrode with contact openings for the source/drain regions. A polysilicon gate structure  24  is formed including the formation of Shallow Trench Isolation (STI) regions  18  between the gate structures. After the source and drain areas  12  and  14  have been implanted to form the source/drain junctions, the sidewall spacers (not shown) are formed. Spacers can be made using silicon-nitride or silicon-oxide, BSG, PSG, polysilicon, other materials preferably of a dielectric nature, CVD oxide formed from a TEOS source. Often used are amorphous materials that inhibit the deposition of epitaxial silicon thereupon. 
     A thick (2-layer deposition) layer  70  of undoped oxide is deposited over the gate electrode  24 , the adjacent STI regions  18  and the exposed surface of the semiconductor substrate  13 . Over this layer  70 , a layer  72  of boronphosphosilicate glass (BPSG) needs to be added for conventional contacts. Contact holes  26  are opened in layer  72  and layer  70  down to the source/drain regions, these contact openings typically have a width of between 0.20 and 0.30 um. 
     FIG. 2 shows the effect that exposure to wet cleaning can have on the surface of the STI areas. Gate electrode  24  is shown together with gate spacers  22  and an adjacent STI region  18 . The surface  27  of the STI  18  shows two irregularities in the areas  28  and  29  where this surface  27  interfaces with the surface of the semiconductor substrate  13 . During the formation of the STI region, the silicon in the areas  28  and  29  can be exposed by wet cleaning. The exposed silicon can be salicided at that time and can therefore cause leakage currents to occur. On the other hand, a thicker silicide layer can result in higher leakage current especially for shallow junction devices. 
     The salicide process further has a limitation related to the fact that the gate and the source/drain silicides are formed at the same time. On the gate, it is desirable for the silicide to have the lowest possible sheet resistance (so the gate electrode will have a low interconnect resistance). To achieve this, a thick silicide layer is needed. Over the source/drain regions, however, the silicide can only be of limited thickness in order to prevent excess consumption of the substrate silicon by silicide formation. Thus, a thicker silicide, though favorable at the gate level, is detrimental to shallow junction devices. 
     U.S. Pat. No. 5,731,239 (Wong et al.) discloses a process for a FET with TiSi 2  S/D contacts  26  and CoSi x  gate contacts  30 , see col. 7, lines 4 to 14. A main purpose of the invention is to form two different material silicide layers over (a) the gate and (b) the S/D. This patent uses CMP to remove a second layer of insulator with Si 3 N 4  as a stop layer. 
     U.S. Pat. No. 5,352,631 (Sitaram et al.) shows a method of forming a FET with a first Metal Silicide (e.g. TiSi x ) S/D contacts (see col. 4, lines 16-35) and second metal silicide (e.g., refractory metal, see col. 5, lines 15-17.) gate contacts. See claim  1 . See FIGS. 1 to  5 . A main purpose of the patent is to form two different material silicide layers over (a) the gate and (b) the S/D. This patent forms the silicide first, after which the source/drain regions are formed using ion implant. The top layer of the gate contains TiSi 2 . 
     U.S. Pat. No. 5,447,875 (Moslehi) shows a method for forming 2 different composition Silicide layers over the S/D and Gate. 
     U.S. Pat. No. 5,464,782 (Koh) shows a salicide process using Ti. 
     U.S. Pat. No. 5,710,438 (Oda et al.) shows a Salicide process using Co. 
     U.S. Pat. No. 5,208,472 (Su et al.) shows a salicide process using two spacers. 
     U.S. Pat. No. 5,705,417 (Tseng) shows a salicide process using Ti or Co. 
     U.S. Pat. No. 5,726,479 (Matsumoto et al.) shows a salicide process on a gate with a large contact area. 
     U.S. Pat. No. 5,736,461 (Berti et al.) shows a salicide structure with both TiSi x  and CoSi x  on the S/D and gate. 
     SUMMARY OF THE INVENTION 
     An objective of the invention is to reduce excessive consumption of substrate silicon in the formation of salicide source/drain electrical contacts. 
     Another objective of the present invention is to provide an economical method for the formation of shallow salicide junctions. 
     Another objective of the invention is to eliminate the narrow line width effect for the gate contact region thereby eliminating the effect of increased sheet resistance for smaller gate electrode device dimensions. 
     Another objective of the invention is to eliminate the adverse effect that silicon consumption has on the formation of shallow junctions. 
     Another objective of the invention is to eliminate leakage currents between the source/drain contacts and the gate contact after contact salicidation. 
     Another objective of the invention is to minimize leakage currents of the source and drain regions. 
     In accordance with the objectives of the invention a new method is established to form different silicide layers over the top of the gate electrode and the surface of the source/drain regions. The shallow trench isolation regions are formed in the surface of the semiconductor substrate, a layer of polysilicon is deposited over the substrate. The gate electrode is patterned, the gate spacers are formed. During this latter process a layer of TiN is formed on the top surface of the gate electrode. The source/drain regions are doped together with the shallow doping under the gate spacers. A layer of Ti is deposited over the gate electrode and the surface of the adjacent source/drain regions and the STI regions, this layer reacts with the silicon of the substrate surface and forms a thin layer of TiSi 2  over the source/drain regions. The unreacted Ti is removed together with the TiN layer on the top surface of the gate electrode making the gate electrode a recessed gate structure. A film of Co is now deposited over the surface of the (recessed) gate electrode, the gate spacers and the area immediately surrounding the gate electrode including the STI areas. This layer of Co reacts with the polysilicon of the top surface of the gate electrode forming CoSi 2 . CoSi 2  has the characteristic that the electrical resistance of lines formed using CoSi 2  is independent of the line width. The unreacted layer of Co is removed leaving the gate electrode with a top surface of CoSi 2  (no line-width effect for making electrical contact with the gate electrode) while the top surface of the source/drain regions consists of a thin layer of TiSi 2  thereby minimizing source/drain region junction leakage currents. By creating a thin layer of TiSi 2  on the surface of the source/drain regions, silicon consumption (that is typical of the Prior Art salicidation process for the formation of contact regions over the source/drain regions) is sharply reduced. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 shows a cross section of a Prior Art gate electrode with source/drain contact points. 
     FIG. 2 shows STI surface damage that can occur by wet cleaning during the formation of the STI regions. 
     FIG. 3 shows cross section of a semiconductor substrate after the deposition of a layer of polysilicon and a layer of TiN. 
     FIG. 4 shows a cross section after the formation of the gate electrode with the gate spacers and the doping of the source/drain regions. 
     FIG. 5 shows a cross section after the deposition of a layer of Ti and the formation of thin layer of TiSi 2  over the source/drain regions. 
     FIG. 6 shows a cross section after simultaneous removal of the unreacted Ti and the removal of the TiN cap from the gate electrode. 
     FIG. 7 shows a cross section after the deposition of a layer of Co. 
     FIG. 8 shows a cross section after the formation of a layer of CoSi 2  on the surface of the gate electrode and the removal of the unreacted Co. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Referring now specifically to FIG. 3, there is shown a cross section of the semiconductor substrate  10 , the Shallow Trench Isolation (STI) areas  12  that have been formed in the surface of the substrate  10 , a layer  14  of polysilicon that has been deposited over the surface of substrate  10  while a layer  16  of TiN has been deposited over the layer of polysilicon  14 . The layer  14  of polysilicon will be patterned to form the gate electrode, the layer  16  of TiN will be patterned to form the top layer or cap of the gate electrode. 
     The layer of polysilicon can be doped as follows: 
     for NMOS: N+ doped using As or P as a dopant with a dopant concentration of between about 1×10 15  and 1×10 20  atoms/cm 3    
     for PMOS: P+ doped using BF 2  or B as a dopant with a dopant concentration of between about 1×10 l5  and 1×10 20  atoms/cm 3    
     Prior technology applied the LOCOS process to create field isolation of devices on a silicon substrate. This process used silicon nitride as a mask and applied selective oxidation of the silicon surface to form the field isolation regions. This process however causes lateral oxidation of the silicon under the nitride mask resulting in the well know bird&#39;s beak effect, where the isolation regions have none-linear and poorly defined vertical boundaries. This resulted in considerable reduction of packaging density. This negative effect is not present when the Shallow Trench Isolation (STI) process is used to form the field isolation regions. Shallow trenches are formed in the silicon substrate by first creating Si 3 N 4  hard mask over the active areas of the silicon substrate. The silicon substrate is etched in the field regions using for instance a RIE etch. The method involves filling the trenches with a chemical vapor deposition (CVD) silicon oxide (SiO 2 ) and then applying an etch back or mechanically/chemically polishing to yield a planar surface. STI regions are formed around the active device to a depth between 2000 and 6000 Angstrom. 
     Polysilicon layer  14  is typically deposited using low-pressure vapor deposition (LPCVD) using, for example, silane (SiH 4 ). The thickness of polysilicon layer  14  is between 1500 and 3000 Angstrom. Layer  16  is preferably deposited by LPCVD using a reactant gas such as SiH 4  or SiH 2 Cl 2 , typically in a temperature range of between 700 and 800 degrees C., to a thickness of about between 1500 and 3000 Angstrom. 
     FIG. 4 shows a cross section after layers  14  and  16  (FIG. 3) have been patterned and etched. The polysilicon gate structure  18  has been created, spacers  22  are formed adjacent to and in contact with the gate structure  18 . A layer  20  of TiN remains on the top surface of the poly gate electrode  18 , layer  20  is also bounded by the gate spacers  22 . Further shown are the implanted source ( 24 ) and drain ( 26 ) regions together with the shallow implants  28  (LDD&#39;s) under the gate spacers  22 . The latter implants of the doped regions will, for purposes of clarity, not be shown in the following figures. 
     Layers  14  and  16  are typically etched using anisotropic etching with an etchant gas of one of the group of CF 4 , CHF 3 , CHCl 3 , CCl 4 , BCl 4  and C 1   2  at a temperature between about 100 and 200 degrees C. Layer  20  of TiN is typically between about 500 and 1500 Angstrom thick. 
     The LDD implant is typically performed as follows: 
     For NMOS: As—energy 1 to 10 keV 
     —dose 1e14 to 1e16 atoms/cm 2    
     For PMOS: BF 2 —energy 1 to 10 keV 
     —dose 1e14 to 5e15 atoms/cm 2 . 
     It must be emphasized at this point that the source/drain formation takes place before the formation of the surface of the substrate over the source/drain regions where the electrical contacts with the source/drain regions will be established. During conventional practices, the silicide (for the electrical contacts) is formed first after which the ion implant for the source/drain regions is performed. In conventional processes a layer of CoSi x  is often formed instead of a layer of silicide because it is easier for the source/drain ion implant to penetrate CoSi x  rather than react with the Ti that is present in the silicide if TiSi 2  is used to prepare the substrate surface for the establishing of the electrical contact points of the source/drain regions. The invention, by first forming the source/drain regions and after that preparing the surface of the substrate for the electrical contact points and by creating a layer on the surface of the substrate that contains TiSi 2 , prevents the problems of conventional processes. 
     Typical separation between the source and the drain region of the gate electrode is 0.2 um. This separation follows from a typical physical gate length of 0.10 um and a spacer width of 0.05 um. 
     Spacers can be made using silicon-nitride or silicon-oxide, BSG, PSG, polysilicon, other materials preferably of a dielectric nature, CVD oxide formed from a TEOS source. Often used are amorphous materials that inhibit the deposition of epitaxial silicon thereupon. A silicon oxide spacer can be formed via anisotropic RIE of said silicon oxide layer, using CHF 3  or CF 4 —O 2 —He as an etchant. A silicon nitride spacer can be formed via anisotropic RIE of said silicon nitride layer, using CHF 3  or SF 6 —O 2  as an etchant. 
     LDD areas for the source and drain regions can be formed immediately after the formation of the spacers by ion implantation for the n +  and the p +  contacts followed by annealing. 
     The source/drain implant  24 / 26  is typically performed as follows, this implant forms the S/D regions  24 / 26 . 
     Conditions for implant  24 / 26  are as follows: 
     For n + /p +  NMOS: As—energy: 15 to 100 keV 
     —dose: 1e14 to 5e16 atoms/cm 2    
     P—energy: 10 to 100 keV 
     —dose: 1e16 to 5e16 atoms/cm 2    
     Typical conditions for the doping are as follows: 
     For PMOS: B—energy: 1 to 50 keV 
     —dose: 1e13 to 1e16 atoms/cm 2    
     BF2—energy: 5 to 180 keV 
     —dose: 1e13 to 1e16 atoms/cm 2    
     FIG. 5 shows the deposition of a blanket layer  30  of Ti that is deposited over the surface of the top layer  20  of the gate electrode  18 / 20 , the exposed sides of the spacers  22 , the surface of the source/drain regions  24 / 26 , (FIG. 4) and the adjacent STI areas  12 . The main purpose of layer  30  is to form reactant layers  31  of TiSi 2  over the surface of the source/drain regions  24 / 26  (FIG.  4 ). The silicon of the substrate reacts with the layer of Ti forming TiSi 2 , this reaction is an annealing process. No TiSi 2  forms over the gate due to the presence of the TiN cap layer  20 . 
     Layer  30  of Ti can be deposited by physical sputtering from a Ti target to a thickness of between about 150 and 450 Angstroms. 
     The annealing process of the Ti film into the substrate over the source/drain regions is typically a Rapid Thermal Annealing (RTA) process at a temperature of between about 600 and 850 degrees C. for a time between about 20 and 60 seconds. 
     A typical annealing process is rapid thermal annealing in a temperature range of between about 600 and 850 degrees C. for a time between about 20 and 60 seconds used to activate the dopants and to form reactant layers  31  of TiSi 2 . A second temperature step of about 850 degrees C. in nitrogen (N 2 ) or argon can be carried out to lower the TiSi 2  sheet resistance and to complete the TiSi 2  phase of the reaction. 
     FIG. 6 shows the simultaneous removal of the unreacted layer  30  (FIG. 5) of Ti and the removal of the top layer  20  (FIG. 5) of TiN of the gate electrode  18 / 20  (FIG.  3 ). 
     A typical process to remove the unreacted Ti is a wet etch, such as deionized water (DI) with 30% hydrogen peroxide (H 2 O 2 ) and ammonium hydroxide (NH 4 OH) 
     FIG. 7 shows a cross section after a blanket deposition of a layer  34  of Co. The Co will chemically react by annealing with the poly of the gate  18  and create a layer of CoSi 2  at the interface between the Co and the poly. No reaction occurs between the deposited layer of Co and the TiSi 2  of layer  31 . Layer  34  is typically deposited to a thickness of between about 100 and 300 Angstrom. 
     The cobalt anneal is typically performed at a temperature between about 500 and 850 degrees C. at atmospheric pressure or in a N 2  environment (also under atmospheric pressure) for a time between about 20 and 60 seconds. 
     Layer  34  is deposited using a PVD sputtering process. 
     FIG. 8 shows the results after removing the unreacted Co. The top surface of the gate electrode now contains layer  36  of CoSi 2 . CoSi 2  does not, as previously pointed out, have the small line effect, line resistance will therefore remain low and independent on the width of the line. This characteristic is clearly an important advantage for the creation of increasingly smaller devices. A further advantage of the creation of the top surface  36  of the electrode containing CoSi 2  is that CoSi 2  is of smaller grain size when compared with the frequently formed top surface of TiSi 2  for the top surface of the gate electrode. This brings the added advantage that electrical contact with the gate electrode is easier to establish while this contact has improved characteristics of reliability as compared with Prior Art electrical contacts. 
     The CoSi 2  anneal is typically performed at a temperature between about 500 and 850 degrees C. at atmospheric pressure or in a N 2  environment (also under atmospheric pressure) using a RTA process for a time between about 20 And 60 seconds. 
     From the cross section shown in FIG. 8 it is clear that the following objectives have been obtained: 
     the top surface of the gate electrode contains CoSi 2 . CoSi 2  is of smaller grain size than conventional TiSi 2  and thereby forms a better contact interface. 
     the top surface of the gate electrode contains CoSi 2 . CoSi 2  does not have the line-width effect, which means that the line resistance for the electrical contact that is to be established with the top of the gate electrode is not dependent on the width of the gate contact area. The line resistance for conventionally used TiSi 2  is highly dependent on the line width. 
     The top surface of the substrate in the source/drain regions contains TiSi 2  which means that less silicon substrate was consumed in forming electrical contact areas for the source/drain regions when compared with typically used Co. The comparative numbers are that, per Angstrom of deposited metal to form electrical contacts, 2.27 Angstrom of silicon substrate is used for the case where the surface of the substrate contains a TiSi 2  interface as opposed to 3.64 Angstrom for a typical interface that contains Co. 
     The top surface of the substrate in the source/drain regions contains TiSi 2 , which minimizes surface junction leakage currents in the source/drain regions because now silicon atoms form the dominant diffusion species in these regions and avoid the possible CoSi 2  spiking problem that is currently widely reported. 
     In sum: the invention provides better contact characteristics for the gate electrode, no narrow line effect for the gate electrode contact, less silicon consumption in forming the metal contacts with the source/drain regions (which facilitate the formation of shallow junctions), minimized surface leakage currents in the source/drain regions. 
     While the present invention has been described with reference to an illustrative embodiment, this description is not to be construed in a limiting sense. Various modifications and combinations, as well as other embodiments of the invention reference to the description. It is therefore intended that the appended claims encompass any such modifications or embodiments.