Abstract:
A device includes an embedded MIM capacitor and a transistor formed in parallel with reduced processing steps and improved device performance in different regions of a substrate. The embedded MIM capacitor has a bottom electrode, an insulator layer, a dielectric film, and a top electrode. The substrate has an insulator region. The bottom electrode, having a first conductor, overlies the insulator region. The insulator layer overlies the substrate and the bottom electrode. The insulator layer has an opening connecting parts of the bottom electrode. The dielectric film lines the opening, and is disposed directly on the bottom electrode and sidewalls of the opening. The top electrode, having a second conductor, overlies the dielectric film in the opening. The dielectric film lines sidewalls and bottom of the top electrode.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     This invention relates to metal-insulator-metal (MIM) capacitor structures and more particularly to a device comprising an MIM capacitor structure and adjacent metal gate electrode CMOS transistor and a method for forming the same in parallel to reduce a processing cost, improve a process flow, and improve both MIM capacitor and CMOS transistor performance in high speed applications. 
     2. Description of the Related Art 
     Advances in technology have resulted in an increasing demand for system-on-chip products where both analog and digital signal processing are desirable. Increasingly it is advantageous for both the analog circuitry and digital circuitry to be in close proximity. For example, digital and analog circuitry blocks operating together are referred to as mixed mode systems. 
     Polysilicon-insulator-polysilicon (PIP) capacitors are well known in the art and have been used in conventional mixed mode systems. Formation of PIP capacitors is, however, problematic in CMOS process technologies used to form a logic circuit on an adjacent region of a chip. In addition, PIP capacitors have unacceptable performance including unstable capacitance with varying applied voltages, primarily due to carrier depletion effects. Moreover, PIP capacitors have the additional shortcoming of difficult scale down as well as exhibiting poor performance in high speed applications. Thus, these and other shortcomings make PIP capacitors undesirable for use in future mixed mode circuitry applications. 
     Metal-insulator-metal (MIM) capacitors have been found to have improved performance over PIP capacitors. Several conventional difficulties conventional processes remain to be overcome. For example, MIM capacitors are generally formed as BEOL processes, adding to processing steps and cost, as well as presenting process integration challenges with both FEOL and BEOL CMOS processes including damascene interconnect processes. 
     Many analog and mixed mode systems rely on precise reproducibility in the electronic properties of circuit component structures, such as MIM capacitor structures, to achieve the electrical matching of the various circuitry components. Electronic mismatching of circuitry components results in degraded signal processing quality and is adversely affected by deviations in critical dimensions between components. Critical dimension deviation is typically exacerbated by the increased number of processing steps required for producing a component, such as a MIM capacitor in a BEOL process. 
     Thus, an improved MIM capacitor structure and manufacturing process achieving reduced cost and improved performance of both MIM capacitors and CMOS transistors including mixed mode systems is desirable. 
     BRIEF SUMMARY OF THE INVENTION 
     The invention provides devices comprising a capacitor and a transistor and methods of forming the same. 
     The invention provides a device comprising a substrate, a bottom electrode, a dielectric film, and a top electrode. The substrate comprises an insulator region. The bottom electrode comprises a first conductor and overlies the insulator region. The dielectric film overlies the bottom electrode, remaining parts of the bottom plate exposed. The top electrode comprises a second conductor and overlies the dielectric film. The dielectric film lines sidewalls and bottom of the top electrode. 
     The invention further provides a device comprising a capacitor and a transistor. The device comprises a substrate, a bottom electrode, a dielectric film, a second metal, and an insulator layer. The substrate comprises a mixed mode region adjacent to a logic circuit region. The bottom electrode comprises a first metal and overlies an insulator region in the mixed mode region. The dielectric film overlies the bottom electrode and a semiconductor region in the logic circuit region, respectively acting as a capacitor dielectric film and a gate dielectric. The second metal overlies the dielectric film, respectively acting as a top electrode of a capacitor structure in the mixed mode region and a real gate electrode of a transistor structure in the logic circuit region. The dielectric film lines sidewalls of the top electrode and the real gate electrode. The insulator layer overlies the capacitor structure and the transistor structure. 
     The invention further provides a method for forming a device comprising a capacitor and a transistor. A substrate is first provided. The substrate comprises an insulator region adjacent to a semiconductor region. A bottom electrode is then formed on the insulator region. The bottom electrode comprises a first conductor. A dielectric film is then formed on the bottom electrode and the semiconductor region, respectively acting as a capacitor dielectric film and a gate dielectric. Finally, a second conductor is formed on the capacitor dielectric film and the gate dielectric, respectively acting as a top electrode of a capacitor structure and a real gate electrode of a transistor structure. 
     The invention further provides a method for forming a device comprising a capacitor and a transistor. A substrate is first provided. The substrate comprises an insulator region adjacent to an active region. A bottom electrode is then formed on the insulator region. The bottom electrode comprises a first conductor. A first gate structure is then formed on the bottom electrode while simultaneously forming a second gate structure on the active region. Gate electrode portions of the first and second gate structures are then removed, respectively forming a first and a second opening, respectively exposing the bottom electrode and the semiconductor region. A dielectric film is formed, lining the first and second openings, forming a capacitor element on the bottom electrode while simultaneously forming a gate dielectric on the active region. Finally, a second conductor is formed, filling the first and second openings, respectively forming a top electrode of a capacitor structure and a real gate electrode of a transistor structure. 
     The invention further provides a device comprising a capacitor and a transistor. The device comprises a substrate, a bottom electrode, a dielectric film, and a second conductor. The substrate comprises an insulator region adjacent to a semiconductor region. The bottom electrode is disposed on the insulator region and comprises a first conductor. The dielectric film is disposed on the bottom electrode and the semiconductor region, respectively acting as a capacitor dielectric film and a gate dielectric. The second conductor is disposed on the capacitor dielectric film and the gate dielectric, respectively acting as a top electrode of a capacitor structure and a real gate electrode of a transistor structure. 
     Further scope of the applicability of the invention will become apparent from the detailed description given hereinafter. It should be understood, however, that the detailed description and specific examples, while indicating preferred embodiments of the invention, are given by way of illustration only, since various changes and modifications within the spirit and scope of the invention will become apparent to those skilled in the art from this detailed description. 
     A detailed description is given in the following embodiments with reference to the accompanying drawings. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The invention can be more fully understood by reading the subsequent detailed description and examples with references made to the accompanying drawings, wherein: 
         FIGS. 1A-1G  are cross-sectional views of a portion of an exemplary device including an MIM structure and a CMOS device at processing stages according to an embodiment of the invention. 
         FIG. 2  is a process flow diagram including several embodiments of the invention. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     The following description is of the best-contemplated mode of carrying out the invention. This description is made for the purpose of illustrating the general principles of the invention and should not be taken in a limiting sense. The scope of the invention is best determined by reference to the appended claims. 
     While the embedded MIM capacitor structure and method for forming the same according to the invention is described with reference to an exemplary mixed mode device including an adjacent CMOS transistor (e.g., MOSFET) device (e.g., on the same chip), It will be appreciated by those skilled in the art that the method of the invention may be used in the formation of other devices including adjacent capacitors (charge storing devices) and transistors such as analog RF circuitry and DRAM devices, where an MIM capacitor structure and transistor gate structure are advantageously formed in parallel. 
       FIGS. 1A-1G  show an exemplary embodiment of the invention at stages in manufacture in forming an embedded (mixed mode) MIM capacitor structure.  FIG. 1A , for example, shows a semiconductor substrate (e.g., chip portion of a semiconductor processing wafer) including mixed mode region  10 A juxtaposed with logic circuit region  10 B to illustrate parallel processes. The semiconductor substrate may be any semiconductor. For example, the semiconductor substrate may include, but is not limited to, silicon, silicon on insulator (SOI), stacked SOI (SSOI), stacked SiGe on insulator (S—SiGeOI), SiGeOI, and GeOI, and combinations thereof. 
     Still referring to  FIG. 1A , shown in the respective mixed mode  10 A and logic region  10 B are isolation (insulator) regions  12 A and  12 B, which may be shallow trench isolation (STI) structures, a LOCOS (local oxidation) region, or a filed oxide region formed by conventional thermal oxidation and/or CVD processes as are known in the art. A dummy gate dielectric material (e.g., silicon oxide) layer  13  is then formed over the substrate surface by conventional CVD and/or thermal oxide growth processes. 
     Still referring to  FIG. 1A , a bottom conductor electrode material  14 , preferably including a metal, is then formed over the dummy oxide layer  13  by conventional processes, including PVD, CVD, electrodeposition, or similar, as is appropriate for the material being deposited. The bottom electrode may be any metal containing conductor including W, WN, Ti, TiN, Mo, TaN, Cu, CuAl, and combinations thereof. Metals are preferred for reduced electrical resistance and high speed applications. 
     Referring to  FIG. 1B , a conventional lithographic patterning and etching process is then carried out to pattern a bottom electrode portion  14 A over the mixed mode region  10 A of the substrate, while removing the bottom electrode material  14 A over the logic region  10 B of the substrate to expose the dummy dielectric layer  13 . For example, a resist etching mask pattern (not shown) is first formed followed by an etching process. It will be appreciated by those skilled in the art that a dry and/or wet etching process may be used, preferably anisotropic, to pattern the bottom electrode portion  14 A. 
     Referring to  FIG. 1C , conventional CMOS manufacturing processes are then carried out to form a dummy gate structure e.g.,  16 A over the mixed mode region  10 A of the substrate while simultaneously forming gate structures e.g.,  16 B and  16 C over the logic region,  10 B, of the substrate. For example, a gate electrode material such as polysilicon is deposited by conventional processes, e.g., PECVD, LPCVD, followed by a lithographic patterning and etching process to form sacrificial gate electrode portions e.g.,  18 A,  18 B,  18 C. LDD regions e.g.,  20 A are then formed adjacent either side of the active gate electrode portions, e.g.,  18 B, by an ion implantation process, followed by formation of sidewall spacers e.g.,  22 A,  22 B, and  22 C, on either side of the respective gate electrode portions to form respective gate structures  16 A,  16 B, and  16 C. Source/drain regions, e.g.,  24 A are then formed by a conventional ion implantation process adjacent to either side of the sidewall spacers, e.g.,  22 B of the active gate structures e.g.,  16 B. Self-aligned silicide (salicide) regions, e.g.  25 A may be optionally formed over the respective source/drain regions, e.g.,  24 A, by conventional processes e.g., forming a metal silicide such a TiSi 2  or CoSi 2 . 
     It will be appreciated by those skilled in the art that ion implantation processes for forming LDD regions and source/drain regions need not be, and preferably are not, carried out for dummy gate structures e.g.,  16 A and  16 C. For example, dummy gate structures having about the same dimensions as active gate structure  16 B, such as  16 C, may be formed on isolation (insulator) regions (e.g.,  12 B) of the logic region  10 B adjacent active gate structure (e.g.,  16 B) to aid in anisotropic etching process window control as well as improving a planarizing process such as chemical mechanical polishing (CMP) in subsequent processes outlined in the following. It will also be appreciated by those skilled in the art that dummy gate structure  16 A on the mixed mode region  10 A, subsequently used to form an MIM capacitor structure, will be wider than the active gate structure  16 A, for example by a factor of two or greater, to provide a sufficient capacitance value. 
     Still referring to  FIG. 1C , a first insulator layer  26 A, also referred to as a pre-metal dielectric (PMD) or interlevel dielectric (ILD), is then deposited over the process surface including substrate regions  10 A and  10 B, followed by a conventional CMP process to planarize the surface to form the insulator layer  26 A about co-planar with and surrounding (adjacent) the gate structures. The insulator layer  26 A may be an conventional insulator material such as doped or undoped silicon oxide formed by spin-on, CVD, or PECVD processes, including such materials such as BTEOS, PTEOS, BPTEOS, PE oxide as well as low-k dielectrics such as carbon doped oxide and organo-silane glass (OSG). 
     Referring to  FIG. 1D , a plasma etching process is then carried out to selectively remove the gate electrode portions e.g.,  18 A,  18 B,  18 C of the respective gate structures, to form respective gate electrode openings e.g.,  19 A,  19 B, and  19 C. It will be appreciated by those skilled in the art by those skilled in the art that the process surface may be lithographically patterned to form a resist etching mask (not shown) prior to etching. The etching process is preferably a plasma etching process e.g., anisotropic reactive ion etching (RIE) process. The etching process is carried out to expose the dummy dielectric layer  13  on the logic region  10 A, and expose the bottom electrode  14 A on the mixed mode region  10 A. Following removal of the gate electrode material, a subsequent wet or dry etching process is carried out to remove the dummy dielectric (dummy oxide) layer  13  overlying the substrate at the bottom of gate electrode openings e.g.,  19 B and  19 C, while leaving the bottom electrode  14 A in place at the bottom of the gate electrode opening  19 A. 
     Referring to  FIG. 1E , a dielectric film  28 , preferably a high-K dielectric film, for example, with a dielectric constant greater than about 10, more preferably greater than about 20, is then conformally deposited by conventional processes, e.g., PVD, CVD, processes including atomic layer (ALCVD) to line (cover sidewall and bottom portions) the gate electrode openings e.g.,  19 A,  19 B, and  19 C. The high-K dielectric material film  28 , for example, may include, but is not limited to high-K dielectrics such as tantalum oxide (e.g., TaO 2 ), tantalum pentaoxide (e.g., Ta 2 O 5 ), hafnium oxide (e.g., HfO 2 ), aluminum oxide (e.g., Al 2 O 3 ), indium oxide (e.g., InO2), lanthanum oxide (e.g., LaO 2 ), zirconium oxide (e.g., ZrO 2 ), yttrium oxide (e.g., Y 2 O 3 ), and combinations thereof. It will be appreciated by those skilled in the art that the thickness of the film will depend in part on design constraints of the CMOS gate dielectric structures as well as a desired capacitance of an MIM structure, e.g., 50 Angstroms to 1000 Angstroms. 
     Still referring to  FIG. 1E , following deposition of the high-K dielectric film  28 , an upper conductor material layer  30 , preferably including a metal, including the same or different conductor material as that used for the bottom electrode  14 A, is deposited by conventional processes e.g., one or more of CVD, PVD, or electrodeposition, to fill the remaining portions of the gate structure openings over the high-K dielectric film. Conductor material layer  30  formation will additionally include forming an excess thickness portion overlying the surface in a blanket deposition process. A metal conductor material is preferred for reduced electrical resistance in high speed applications. 
     Referring to  FIG. 1F , a planarizing process, preferably a CMP process, is then carried out to remove excess conductor material layer  30  and excess dielectric film  28  overlying the insulator layer  26 A surface, to simultaneously planarize and complete formation of MIM capacitor structure (formerly dummy gate structure  16 A) with an upper metal conductor electrode  30 A over a dielectric capacitor element  28 A in mixed mode region  10 A. Gate structures  16 B and  16 C including metal conductor gate electrodes  30 B and  30 C are simultaneously formed over the logic region  10 B and over respective gate dielectric portions  28 B and  28 C, wherein the gate electrode  30 B is a real gate electrode. It will be appreciated by those skilled in the art that the MIM capacitor and gate structures will be about co-planar following the CMP planarization process. 
     Referring to  FIG. 1G , conventional processes are then carried out to form a second insulator (e.g., ILD) layer  26 B including the same or different material as first insulator layer  26 A is then formed over the MIM capacitor structure  16 A and gate structures  16 B and  16 C, followed by formation of conductive contacts by a damascene process, e.g.,  32 A,  32 B, to make electrical contact with the MIM capacitor electrodes, and  32 C to make electrical contact with the source/drain regions e.g.,  24 A of active transistor structure  16 B. 
       FIG. 2  is a process flow diagram including several embodiments of the invention. In process  201 , a bottom electrode conductor is formed over an insulator region including a first region of a substrate. In process  203 , a dummy gate structure is formed over the bottom electrode in parallel with formation of an active gate structure on a second region of the substrate. In process  205 , a first ILD layer is formed adjacent gate structures. In process  207 , the gate electrode portions of the gate structures are removed to form respective gate structure openings. In process  209 , a high-K dielectric film is formed to line the first and second gate structure openings. In process  211 , a second conductor is formed to fill the first and second gate structure openings. In process  213 , a planarization process (CMP) is performed to remove excess second conductor and high-K dielectric over the surface to form an MIM capacitor from the dummy gate structure and a CMOS transistor from the active gate structure. In process  215 , a second ILD layer is formed to include electrical contacts to the MIM capacitor electrodes and the CMOS transistor. 
     Thus a device, such a mixed analog/digital (logic) device, an RF analog device, or a DRAM device including both an MIM capacitor structure and CMOS gate structure are achieved. The MIM capacitor and CMOS gate structure are formed in parallel with reduced processing steps and improved device performance. The CMOS gate structure and MIM capacitor electrodes with a metal conductor material, for example, improve the performance (e.g., operating speed) of the CMOS gate structure, thereby improving the operation of the mixed mode device. A conductor (e.g., metal) CMOS gate electrode, e.g., a metal-oxide-semiconductor (MOSFET) improves device speed by overcoming the depletion effects of polysilicon. Formation of the MIM capacitor formed by parallel compatible processes reduces the number of required processing steps and improves voltage-capacitance linearity. By utilizing the same high-K dielectric film for the MIM capacitor and the CMOS gate dielectric, processing steps are further reduced, and the capacitance of the MIM structure and the performance of the CMOS gate structure are improved, e.g. short channel effects (SCE) are reduced. Thus, both the MIM capacitor and CMOS gate structure can be scaled down with reduced cost and achieve gate improved performance for high speed applications. 
     While the invention has been described by way of example and in terms of preferred embodiment, it is to be understood that the invention is not limited thereto. To the contrary, it is intended to cover various modifications and similar arrangements (as would be apparent to those skilled in the art). Therefore, the scope of the appended claims should be accorded the broadest interpretation so as to encompass all such modifications and similar arrangements.