Abstract:
A process uses two layers of polysilicon for fabricating high-density nonvolatile memory, such as mask ROM or SONOS memory, integrated with advanced peripheral logic on a single chip. The method includes covering a gate dielectric layer with a sacrificial layer of silicon nitride; using a masks for defining line structures in the layer of silicon nitride for the bit line implant processes; depositing a dielectric material among the line structures to fill gaps among the line structures; planarizing the deposited oxide and said layer of silicon nitride; removing the silicon nitride and applying a layer of polysilicon material; patterning wordlines in the array portion, and transistor gate structures in said non-array portion, and applying LDD, silicide and other logic circuit processes.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to manufacturing non-volatile memory, having small critical dimensions, particularly suited as embedded memory on complex integrated circuits. 
     2. Description of Related Art 
     As the size of components on integrated circuits shrinks, the degree of integration of functional units on a single chip is increasing. Thus, many chips are being designed which include embedded nonvolatile memory along with logical components, such as memory controllers, general-purpose processors, input/output interface logic, dedicated logic, digital signal processors, and a wide variety of other functional units. 
     The small dimensions of components on complex integrated circuits present design difficulties. For example, the small width of diffusion conductors increases the resistance of the conductors. Thus, it is known to use technology known as salicide, or other technology, to form a highly conductive layer on the surface of the diffusion conductors to decrease the resistance. According to the well-known salicide process, a silicide such as titanium silicide is formed on the surface of the diffusion conductors using a self-aligned deposition process. However, application of the salicide process is incompatible with some processes for forming high-density memory cells. 
     For example, one step used in the salicide process is sidewall formation. The sidewalls are used for masks in the self-alignment step. Sidewall formation includes an etch step, often a plasma based etch, by which the layer of oxide, or other sidewall material, is etched back to the underlying dielectric layer in regions over diffusion conductors. This etch back step can damage the surface of the silicon substrate, resulting in a damaged surface across which a leakage path can be formed. This leakage path can be damaging particularly in high-density memory arrays, causing soft breakdown of the memory. 
     Another problem that arises because of the high-density of modern technologies is the so-called short channel effect. Because the channel lengths in small dimension transistors are so small, diffusion of dopants implanted to form source and drain regions due to oxidation and thermal processes that occur after the implant can undesirably shorten the channels of the transistors. These effects occur because of so-called thermally enhanced diffusion TED and so-called oxidation enhanced diffusion OED. 
     It is desirable, therefore, to provide a manufacturing process suitable for combined manufacturing of high-density nonvolatile memory with advanced logic peripheral circuits, which reduces or minimizes effects of small dimension components, such as the short channel effect, the soft breakdown effect due to oxide damage, the high resistance of narrow diffusion conductors, and the like. 
     SUMMARY OF THE INVENTION 
     The present invention provides a process using a sacrificial protective layer for fabricating high-density nonvolatile memory, such as mask ROM or SONOS memory, integrated with advanced peripheral logic on a single chip. An embodiment of the present invention provides a method for manufacturing an integrated circuit on the substrate, including nonvolatile memory in an array portion of the substrate and other circuitry in a non-array portion of the substrate. The method includes integrated circuit manufacturing steps comprising: 
     forming gate dielectric layers in the array portion and in the non-array portion of the substrate; 
     covering the gate dielectric layer with a protective, sacrificial layer, comprising for example silicon nitride, in the array portion and in the non-array portion of the substrate; 
     patterning lines in a bitline direction in the array portion, and etching said protective layer to form line structures; 
     implanting dopants into the substrate through the gate dielectric layer between the line structures; 
     depositing a dielectric material between the line structures to fill gaps between the line structures; 
     planarizing the array portion and the non-array portion to a level exposing said line structures and silicon nitride layer, and said dielectric material in the gaps between the line structures; 
     removing said protective layer from said non-array portion and said line structures from said array portion, leaving the gate dielectric layers and the remaining portions of said dielectric material filling the gaps between the line structures; 
     covering the remaining portions of the gate dielectric layers and said dielectric material filling the gaps between the line structures with a layer of polysilicon material; 
     patterning wordlines in the array portion, and transistor gate structures in said non-array portion, and etching said layer of polysilicon according to the patterning, to form wordlines in the array portion and transistor gate structures in the non-array portion; 
     implanting dopants to form source and drain regions in the non-array portion; 
     forming self aligned silicide in source and drain regions in the non-array portion; 
     applying a dielectric layer over the array portion and the non-array portion; and 
     applying patterned metallization over the dielectric layer. 
     The sacrificial, protective layer comprises silicon nitride in various embodiments having an as deposited thickness of around 300 Angstroms, and preferably in a range of about 100 to about 1000 Angstroms. The polysilicon layer as deposited in various embodiments has a thickness of around 1500 Angstroms, and preferably in a range of about 1300 to about 1600 Angstroms. 
     Embodiments of the invention also include so-called lightly doped drain LDD processes to improve transistor performance, particularly in the peripheral circuitry. Thus, in embodiments including the LDD processes, the method of implanting dopants to form source and drain regions in the non-array portion includes implanting a first dopant aligned with the transistor gate structures, forming sidewall spacers on the transistor gate structures, and implanting a second dopant aligned with the sidewall spacers. Silicide is formed, in these LDD embodiments, using processes self-aligned with the sidewall spacers. In some embodiments, the sidewall spacers are made using silicon nitride, or other material that is different than the material of the deposited dielectric and gate dielectric layer, so that a selective etch process can be used during formation of the sidewall spacers, to minimize damage of the underlying gate dielectric layer. 
     Embodiments of the invention use chemical vapor deposition to deposit the dielectric material among the gate structures to fill gaps among the gate structures. Preferably, plasma enhanced chemical vapor deposition, or another low-temperature chemical vapor deposition process, is used. For example, deposition processes in which the deposition temperature is less than 650 degrees Celsius are preferable. 
     The step of planarizing is accomplished using chemical mechanical polishing in embodiments of the manufacturing method, to further reduce the thermal “budget” on the manufacturing process. 
     The manufacturing process outlined above is applicable to mask ROM embedded memory arrays, as well as to embedded, electrically programmable and erasable memory arrays using so-called SONOS memory cells, which have gate dielectrics based on a composite layer, including a bottom dielectric layer, such as silicon dioxide, a charge trapping dielectric layer such as silicon nitride, and a top dielectric layer, such as silicon dioxide. 
     Thus, the present invention provides a fabrication process relying on two polysilicon layers for embedded flat mask ROM arrays, and embedded flat SONOS arrays, in complex integrated circuits. Source and drain buried diffusion layers are formed using an implantation process after formation of the gate dielectric and the dielectrics isolating the diffusion bitlines from the wordlines, reducing the thermally enhanced diffusion and oxidation enhanced diffusion effects that may cause a short channel. The low-temperature deposition and chemical mechanical polishing processes form thick dielectric layers between wordlines, to prevent soft breakdown between buried diffusion layers and wordlines. The polysilicon layer is used to form transistor gate structures for the peripheral circuitry. A silicon nitride sidewall spacer process is used to enhance etch selectivity during formation of the sidewalls, preventing spacer etch damage of dielectric layers and reducing the problems with leakage caused by damage to surfaces on the dielectrics between buried diffusion regions. 
     Other aspects and advantages of the present invention can be seen on review of the drawings, the detailed description and the claims, which follow. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIGS. 1A and 1B are a flow diagram illustrating a manufacturing process according to the present invention. 
     FIGS. 2-10 illustrate structures at steps in an embodiment of the manufacturing process for a complex integrated circuit including an embedded mask ROM. 
     FIG. 11 illustrates application of the process of FIGS. 2-10 to an embedded non-volatile memory based on SONOS cells. 
    
    
     DETAILED DESCRIPTION 
     A detailed description of embodiments of the present invention is provided with reference to the figures, in which FIGS. 1A and 1B illustrate a basic flow for the manufacturing process. The structures at various steps in the manufacturing process are shown in FIGS. 2-10 for mask ROM based embedded memory devices. FIG. 11 illustrates application of the process to SONOS based embedded memory devices. 
     A first step in the manufacturing process is to form isolation structures that define an array portion  110  and a non-array portion  111  of the substrate (block  10 ). FIG. 2 provides a view of a resulting structure. In the example shown in FIG. 2, the array portion  110  is isolated from the non-array portion by dielectric region  112 . The dielectric region  112  is formed by depositing oxide or other dielectric within a trench, by LOCOS oxidation, or otherwise as known in the art. The non-array portion  111  is divided into an n-channel region and a p-channel region by dielectric regions  113  for typical CMOS implementation of logic circuits. The n-channel region is defined by p-type well  114  in which n-channel devices are formed. The p-channel region is defined by the n-type well  115  in which p-channel devices are formed. In this example, the array portion  110  includes a deep n-type well  116 , in which a p-type well  117  is formed. N-channel memory devices are formed in the p-type well  117 . In one example process, a retrograde well formation process is used to create the deep well structure and to apply Vt implants in the memory cell region. The process includes two retrograde well processes including a well implant—&gt;anti-punch through implant—&gt;and Vt implant using the same mask. Two masking layers are then used in this example to form the n-type well  116  and the p-type well  117  according to the retrograde well approach. For the NMOS devices, representative implant recipes include a Vt implant using BF 2  with 50K˜80K KeV, with a concentration of about 1E12 dose/cm{circumflex over ( )}2, an anti-punch implant using B with 50K˜80K KeV, with a concentration of about 1E12 dose/cm{circumflex over ( )}2, and a well implant using B with 150K˜250K KeV, with a concentration of about 1E13 dose/cm{circumflex over ( )}2. For the PMOS devices, representative implant recipes include a Vt implant using P at 100˜120K KeV, with a concentration of about 2E12 dose/cm{circumflex over ( )}2, an anti-punch implant using P at 250K˜300K KeV, with a concentration of about 2E12 dose/cm{circumflex over ( )}2, and a well implant using P at 550K˜600K KeV, with a concentration of about 1E13 dose/cm{circumflex over ( )}2. This combination of well structures in the array portion  110  is used for isolation purposes in some embodiments. 
     In a next step (block  11 ) of FIG. 1A, a gate dielectric layer  118  is formed in the array portion and a gate dielectric layer  119  is formed in the non-array portion. The gate dielectric layer  118  in the array portion may be formed in the same process step as the gate dielectric layer  119  formed in the non-array portion, or different processes may be used so as to establish different parameters for the gate dielectrics in the various regions. For example, in SONOS based memory embodiments, the gate dielectric layer  118  is implemented with a composite dielectric layer as shown in FIG. 11, while the gate dielectric layer  119  in the non-array portion remains a single layer of silicon dioxide. 
     After formation of the gate dielectric layers  118 ,  119 , a sacrificial, protective layer, comprising silicon nitride in this example, is deposited (block  12 ). The resulting structure is shown in FIG.  3 . Thus, protective layer  125  overlies the gate dielectric layers  118 ,  119 , and in this example has a thickness between about 100 and 1000 angstroms. More preferably, the protective layer  125  comprises silicon nitride around 300 Angstroms thick, such as between about 200 and about 450 Angstroms thick. 
     In a next process step (block  13 ), a bit line pattern on the array portion is defined, and the protective layer is etched to expose the gate dielectric  118  in the array portion leaving line structures in a bit line direction. The protective layer is etched according to a first photoresist pattern, leaving line structures comprising remnants of the protective layer. Next, buried diffusion bit lines are implanted through the exposed gate dielectric using the line structures in the bit line direction as an implant mask (block  14 ). One example recipe for the buried diffusion BD implant includes a “pocket” p-type implant of boron B with an implant energy of 15˜40K KeV, and concentration of 1˜5E13 atom/cm{circumflex over ( )}2, after an n-type BD implant of arsenic As with an implant energy of 30˜60K KeV, and a concentration of 2˜3.5E15 atom/cm{circumflex over ( )}2. Of course, as with all implant processes, these energies and concentrations are fine tuned according to the structures and processes of the particular chip and particular fab. Finally, the second photoresist pattern is stripped. A structure resulting from this process is shown in FIG. 4, which represents a cross-section parallel to the wordline direction in the array. Thus, in the array portion, line structures  126  and  127  are left in the array portion of the substrate. 
     Buried diffusion bit lines  128  and  129  extend in the bit line direction across the array portion. The buried diffusion bit lines  128  and  129  are formed after formation of protective line structures  126  and  127 , so that the process used to form the gate dielectric  118  does not cause oxidation enhanced diffusion. 
     In a next process step (block  15 ), dielectric is deposited in the array portion filling in the gaps between the line structures. The deposition technique in one embodiment comprises chemical vapor deposition or plasma enhanced chemical vapor deposition of a dielectric material comprising silicon dioxide, during which deposition the chamber wall temperature is kept as low as practical, for example less than about 650 degrees Celsius. In one example, the etch chemistry comprises TEOS/O2 mixed-chemical with a chamber wall temperature of 630 degrees Celsius. In embodiments of the invention, other deposition processes may be executed in which the temperature is less than about 650 degrees Celsius. After deposition of the dielectric material, a planarization process is executed. Preferably, low-temperature chemical mechanical polishing CMP is used, rather than for example, a thermal process involving reflow. In processes using chemical mechanical polishing CMP, after deposition of the dielectric material in the gaps the so-called reverse cell gate process is applied to improve CMP uniformity. The reverse cell gate process includes the photoresist pattern, etch, and photoresist pattern strip in order to reduce the pattern density dependence of the deposited dielectric prior to polishing. A resulting structure is shown in FIG. 5, in which oxide lines  170  and  171  fill the gaps between the silicon nitride line structures  126  and  127 , and have a planar top surface. 
     After planarization, the line structures in the array portion and the remaining protective layer in the non-array portion are removed (block  16 ). Next, a layer of polysilicon  130  is deposited on the exposed dielectric (block  17 ). The resulting structure is shown in FIG. 6, in which the line structures in the array portion and the remaining protective layer have been removed and polysilicon layer  130  has been deposited. The polysilicon layer  130  is around 1500 Angstroms thick, such as between about 1300 Angstroms and about 1600 Angstroms. 
     After deposition of the layer  130  of polysilicon, a photoresist pattern is formed to define wordlines in the array portion and gate structures in the non-array portion of the substrate. The layer of polysilicon  130  is etched according to the pattern to expose the underlying gate dielectric layer (block  18 ). The resulting structure is shown in FIG. 7, in which wordline structure  134  is shown. 
     A plan view of the resulting structure is shown in FIG.  8 . Buried diffusion bit lines  128 ,  129  extend vertically on the page in the FIG. 8, and are crossed by the wordline structures  134 . CVD oxide regions, e.g.  132 , fill the gaps between the diffusion bit lines  128 ,  129 . 
     In a next process step, a re-oxidation step followed by lightly doped drain LDD processes are applied, beginning with a first implantation step in the non-array portion, aligned with the gate structures  140 ,  141  (block  19 ). The structure can be seen in FIG. 9, which shows a cross-section parallel with the wordline  134 . This first implantation results in a diffusion region  145  and a diffusion region  146  closely aligned with the sides of the gate structure  140 . Next, silicon nitride sidewall spacers are formed, by depositing a layer of silicon nitride, and then anisotropically etching the silicon nitride down to the underlying structures. One example SiN deposition recipe includes N2/NH3/SiH2C12 mixed-chemical chemical vapor deposition with a chamber wall temperature of 730C. The silicon nitride is etched in one example process using a dry etch (e.g. 75 mt/1600 W/C4F8/Ar/CH3F) where mt means milli-torr and W is watts, mixed-chemical with endpoint set to stop etch process on the SiO2 gate dielectric layer. As seen in FIG. 9, this etch step results in sidewalls, e.g.  150 ,  151 , on the structures on the substrate (block  20 ). The LDD processes in the non-array portion are completed by a second implantation step, aligned with the sidewall spacers (block  21 ). As seen in FIG. 9, this results in the diffusion regions  147 ,  148  aligned with the sidewall spacers  150 ,  151  and spaced away from the sides of the gate structure  140 , while overlapping with the diffusion regions  145  and  146 . The spacers are formed using silicon nitride in this embodiment to improve selectivity of the etch back step used for sidewall formation with the underlying dielectric on the surface of the substrate, and with the CVD dielectric in the array portion of the substrate. Other materials may be used for the sidewall spacers which support select etching relative to the gate dielectric material. 
     In a next step, the self aligned silicide (salicide) process is applied (block  22 ). As seen in FIG. 9, the salicide process forms conductive silicide  149  over the exposed diffusion regions in alignment with the sidewall spacers, on top of the wordline polysilicon, and on top of the gate structures in the non-array portion. The diffusion bit lines in the array portion of the device are protected from salicide process by the CVD dielectric and sidewall structures. 
     Finally, a dielectric layer  160 , contact vias  161  and patterned metallization  162  are applied to complete the device. For mask ROM, code implants are arranged after SiN removal and before the deposition of the layer of polysilicon, in a representative process flow. 
     FIG. 10 shows the structure in a cross-section parallel to the buried diffusion bit line  128  in the array portion. FIG. 10 illustrates the gate dielectric  118  over the buried diffusion bit lines. The silicon nitride sidewall spacers  170  fill between the wordline structures  134 . 
     The process described above is also used for embedded nonvolatile memory arrays that include erasable and programmable memory cells, such as SONOS based memory cells. In this embodiment, the gate dielectric  118  in the array portion is replaced by a composite dielectric layer that includes a charge trapping layer. Thus, as shown in FIG. 11, the gate dielectric in a SONOS based array comprises an ONO stacked gate dielectric. The bottom layer  180  of the composite dielectric typically comprises silicon dioxide. The middle layer  181  is used for charge trapping, and typically comprises silicon nitride. The top layer  182  also typically comprises silicon dioxide. The process flow described above in respect to FIGS. 2 through 10 is identical after this formation of the composite gate dielectric layer in the array portion, and not described again. 
     While the present invention is disclosed by reference to the preferred embodiments and examples detailed above, it is to be understood that these examples are intended in an illustrative rather than in a limiting sense. It is contemplated that modifications and combinations will readily occur to those skilled in the art, which modifications and combinations will be within the spirit of the invention and the scope of the following claims.