Abstract:
A non-volatile memory cell including a semiconductor substrate having a fin shaped upper surface with a top surface and two side surfaces. Source and drain regions are formed in the fin shaped upper surface portion with a channel region there between. A conductive floating gate includes a first portion extending along a first portion of the top surface, and second and third portions extending along first portions of the two side surfaces, respectively. A conductive control gate includes a first portion extending along a second portion of the top surface, second and third portions extending along second portions of the two side surfaces respectively, a fourth portion extending up and over at least some of the floating gate first portion, and fifth and sixth portions extending out and over at least some of the floating gate second and third portions respectively.

Description:
RELATED APPLICATIONS 
       [0001]    This application claims the benefit of U.S. Provisional Application No. 62/134,489, filed Mar. 17, 2015, and which is incorporated herein by reference. 
     
    
     FIELD OF THE INVENTION 
       [0002]    The present invention relates to non-volatile flash memory cell arrays. 
       BACKGROUND OF THE INVENTION 
       [0003]    Currently, split-gate type non-volatile memory cells are known. U.S. Pat. No. 5,029,130 (incorporated by reference for all purposes) describes such a split gate memory cell. This memory cell has a floating gate disposed over and controlling the conduction of a first portion of the channel region, and a word line (control) gate disposed over and controlling the conduction of a second portion of the channel region. The control gate has a first portion disposed laterally adjacent the floating gate and disposed over the channel region second portion, and the control gate has a second portion that extends up and over the floating gate. Because the channel region is formed along the planar surface of the semiconductor substrate, as device geometries get smaller, so too does total area (e.g. width) of the channel region. This reduces the current flow between the source and drain regions, requiring more sensitive sense amplifiers etc. to detect the state of the memory cell. 
         [0004]    Because the problem of shrinking the lithography size thereby reducing the channel width affects all semiconductor devices, a Fin-FET type of structure has been proposed. In a Fin-FET type of structure, a fin shaped member of semiconductor material connects the source to the drain regions. The fin shaped member has a top surface and two side surfaces. Current from the source to the drain regions can then flow along the top surface as well as the two side surfaces. Thus, the width of the channel region is increased, thereby increasing the current flow. However, the width of the channel region is increased without sacrificing more semiconductor real estate by “folding” the channel region into two side surfaces, thereby reducing the “footprint” of the channel region. Non-volatile memory cells using such Fin-FETs have been disclosed. Some examples of prior art Fin-FET non-volatile memory structures include U.S. Pat. Nos. 7,423,310, 7,410,913 and 8,461,640. However, heretofore, these prior art Fin-FET structures have disclosed using floating gate as a stack gate device, or using trapping material, or using SRO (silicon rich oxide) or using nanocrystal silicon to store charges, or other more complicated memory cell configurations. 
       BRIEF SUMMARY OF THE INVENTION 
       [0005]    An improved non-volatile memory cell includes a semiconductor substrate of a first conductivity type having a fin shaped upper surface portion having a top surface and two side surfaces, and spaced apart first and second regions of a second conductivity type different than the first conductivity type in the fin shaped upper surface portion, with a channel region extending between the first region and the second region. The channel region has a first portion that includes a first portion of the top surface and first portions of the two side surfaces, and has a second portion that includes a second portion of the top surface and second portions of the two side surfaces. A conductive floating gate includes a first portion that extends along and is insulated from the first portion of the top surface, a second portion that extends along and is insulated from the first portion of one of the two side surfaces, and a third portion that extends along and is insulated from the first portion of the other of the two side surfaces. A conductive control gate includes a first portion that extends along and is insulated from the second portion of the top surface, a second portion that extends along and is insulated from the second portion of one of the two side surfaces, a third portion that extends along and is insulated from the second portion of the other of the two side surfaces, a fourth portion that extends up and over and is insulated from at least some of the floating gate first portion, a fifth portion that extends out and over and is insulated from at least some of the floating gate second portion, a sixth portion that extends out and over and is insulated from at least some of the floating gate third portion. 
         [0006]    An improved non-volatile memory array includes a semiconductor substrate of a first conductivity type having a plurality of parallel fin shaped upper surface portions extending in a first direction each having a top surface and two side surfaces, and a plurality of memory cells formed on each one of the fin shaped upper surface portions. Each memory cell includes spaced apart first and second regions of a second conductivity type different than the first conductivity type in the one fin shaped upper surface portion, with a channel region extending between the first region and the second region, wherein the channel region has a first portion that includes a first portion of the top surface and first portions of the two side surfaces, and has a second portion that includes a second portion of the top surface and second portions of the two side surfaces. Each memory cell further includes conductive floating and control gates. The conductive floating gate includes a first portion that extends along and is insulated from the first portion of the top surface, a second portion that extends along and is insulated from the first portion of one of the two side surfaces, and a third portion that extends along and is insulated from the first portion of the other of the two side surfaces. The conductive control gate includes a first portion that extends along and is insulated from the second portion of the top surface, a second portion that extends along and is insulated from the second portion of one of the two side surfaces, a third portion that extends along and is insulated from the second portion of the other of the two side surfaces, a fourth portion that extends up and over and is insulated from at least some of the floating gate first portion, a fifth portion that extends out and over and is insulated from at least some of the floating gate second portion, and a sixth portion that extends out and over and is insulated from at least some of the floating gate third portion. A plurality of control gate lines each extending in a second direction perpendicular to the first direction and electrically connected to one of the control gates for each of the fin shaped upper surface portions. 
         [0007]    A method of forming a non-volatile memory cell includes forming a pair of parallel trenches into a surface of a semiconductor substrate of a first conductivity type resulting in a fin shaped upper surface portion between the trenches having a top surface and two side surfaces, forming insulation material along the top surface and the two side surfaces, forming spaced apart first and second regions of a second conductivity type different than the first conductivity type in the fin shaped upper surface portion with a channel region extending between the first region and the second region (wherein the channel region has a first portion that includes a first portion of the top surface and first portions of the two side surfaces, and has a second portion that includes a second portion of the top surface and second portions of the two side surfaces), forming a conductive floating gate, and forming a conductive control gate. The conductive floating gate includes a first portion that extends along and is insulated from the first portion of the top surface, a second portion that extends along and is insulated from the first portion of one of the two side surfaces, and a third portion that extends along and is insulated from the first portion of the other of the two side surfaces. The conductive control gate that includes a first portion that extends along and is insulated from the second portion of the top surface, a second portion that extends along and is insulated from the second portion of one of the two side surfaces, a third portion that extends along and is insulated from the second portion of the other of the two side surfaces, a fourth portion that extends up and over and is insulated from at least some of the floating gate first portion, a fifth portion that extends out and over and is insulated from at least some of the floating gate second portion, and a sixth portion that extends out and over and is insulated from at least some of the floating gate third portion. 
         [0008]    Other objects and features of the present invention will become apparent by a review of the specification, claims and appended figures. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0009]      FIGS. 1A-1X  are side cross sectional views (along the WL (X) direction) showing the steps in forming the split-gate non-volatile memory cell of the present invention. 
           [0010]      FIGS. 2A-2W  are side cross sectional views (along the BL (Y) direction) showing the steps in forming the split-gate non-volatile memory cell of the present invention. 
           [0011]      FIG. 3  is a top view of the memory cell array layout. 
           [0012]      FIG. 4  is a top view of the memory cell array layout in an alternate embodiment. 
           [0013]      FIGS. 5A-5H  are side cross sectional views (along the WL (X) direction) showing the steps in forming the split-gate non-volatile memory cell of the present invention according to an alternate embodiment. 
       
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       [0014]    The present invention is a Fin-FET configuration for the simple split gate type memory cell that has only two gates, a floating gate and a control gate, where the control gate has a first portion laterally adjacent to the floating gate and a second portion that extends up and over the floating gate. The method of making such a split gate memory cell provide many advantages, including silicon trench etching and partial oxide fill for isolation, and self-aligned components such as the floating gate. 
         [0015]      FIGS. 1A-1Y and 2A-2X  are side cross sectional views showing the process steps in forming the Fin-FET split gate memory cell array.  FIGS. 1A-1X  show the cross section in the word line (X) direction, and  FIGS. 2A-2X  show the cross section in the bit line (Y) direction. The process begins by forming a layer of silicon nitride (“nitride”)  12  on the surface of a silicon substrate  10 . A layer polysilicon (“poly”)  14  is formed on the nitride layer  12 . A second nitride layer  16  is formed on the poly layer  14 . The resulting structure is shown in  FIGS. 1A and 2A . The second nitride layer  16  is patterned using a photo lithography and etch process (i.e. photo resist is deposited, selectively exposed and etched, leaving portions of the nitride layer  16  exposed, which are then etched using a nitride etch). The nitride etch removes all but a pair of blocks of the nitride  16 , as shown in  FIGS. 1B and 2B . 
         [0016]    A layer of silicon dioxide (“oxide”)  18  is formed over the structure, as shown in  FIGS. 1C and 2C . An anisotropic oxide etch is performed to lower the oxide in the BL direction, and leave spacers of the oxide  18  abutting the nitride blocks ( FIGS. 1D / 2 D). The nitride blocks  16  are then removed with a nitride etch ( FIGS. 1E / 2 E). A poly etch is then performed, to remove the exposed portions of the poly layer  14  in the WL direction (except for the poly layer blocks  14  under the oxide spacers ( FIGS. 1F / 2 F). The oxide layer and spacers  18  are then removed with an oxide etch ( FIGS. 1G / 2 G). A nitride etch is used to remove the nitride layer  12  in the WL direction (except for blocks of the nitride layer  12  under the poly blocks  14 ) ( FIGS. 1H / 2 H). A silicon etch is then performed which removes the remaining portions of the poly layer  14 , and also forms trenches  20  into the exposed portions of the silicon substrate  10  in the WL direction ( FIGS. 1I / 2 I). Oxide  22  is then deposited over the structure, followed by a chemical mechanical polish (CMP) using the nitride layer  12  as an etch stop, which fills the trenches with oxide  22  ( FIGS. 1J / 2 J). A partial oxide etch is then performed to recess the oxide  22  in the trenches ( FIGS. 1K / 2 K). A nitride etch is then used to remove the nitride  12  ( FIGS. 1L / 2 L). 
         [0017]    An thin oxide layer  24  (FG OX) is then deposited or grown on the exposed surfaces of the substrate  10 , including those in the trenches  20 . A poly layer  26  (FG Poly) is then formed over the oxide layer  24  ( FIGS. 1M / 2 M). A nitride layer  28  is then deposited on the poly layer (filling trenches  20 , and then planarized using a planarizing etch ( FIGS. 1N / 2 N). Photo resist  30  is then deposited on the structure, and selectively etched using a photolithography process, leaving strips of the photo resist  30  (FGPR) extending in the WL direction (leaving portions of the nitride layer  28  exposed). The exposed portions of the nitride layer  28  are removed by a nitride etch ( FIG. 1O / 2 O). The photo resist  30  is then removed. An oxidation process is used to oxidize the exposed portions of the poly layer  26 , creating regions of oxidized polysilicon  32  (Poly Ox) ( FIGS. 1P / 2 P). The nitride  28  is then removed using a wet nitride etch ( FIGS. 1Q / 2 Q). An anisotropic poly etch is performed to remove those portions of the poly layer  26  not underneath the oxidized poly  32  ( FIGS. 1R / 2 R). 
         [0018]    A word line VT implant (e.g. blanket boron implant) is performed into the surface portions of the substrate  10  adjacent the poly layer  26  and oxidized poly  32  (to control the word line Vt). An oxide layer  34  (Tunnel Ox) is formed (e.g. by HTO deposition) on the oxidized poly  32  and the exposed portions of the poly layer  26  ( FIGS. 1S / 2 S). A poly layer  36  is then formed over the structure ( FIGS. 1T / 2 T). An implantation process is then performed (e.g. N+ implantation) for doping of the poly layer  36 . Photoresist  38  is then deposited over the structure and portions thereof selectively removed by a photolithography etch process, leaving portions of the poly layer  36  exposed by the photo resist  38  in the BL direction. A poly etch is then performed to remove the exposed portions of the poly layer  36  ( FIG. 1U / 2 U). The photoresist  38  is removed, and new photoresist  40  is deposited over the structure and portions thereof selectively removed by a photolithography etch process, leaving portions of the structure exposed by the photo resist  40  in the BL direction. A high voltage implant (HVII implant) is performed to form the source line junction  42  in the surface of the substrate adjacent the FG Poly  26  ( FIGS. 1V / 2 V). An anneal is performed to complete the formation of the source region (SL)  42  in the substrate. A similar implant/anneal can be performed to form the drain region (DR)  44  in the substrate on the other side of the poly layer  36 . The final structure is shown in  FIGS. 1W, 1X and 2W . Additional processing is then performed to form electrical contacts, contact lines, source diffusion lines, etc. which are well known in the art. 
         [0019]    The above described process forms memory cells having a floating gate  26  disposed over the top, and along the sides, of a first portion of the fin shaped channel region  46  of the substrate that extends between the source region  42  and drain region  44  (see  FIGS. 1W and 2W ). The second poly layer  36  is a control gate that has a first portion disposed over the top, and along the sides, of a second portion of the fin shaped channel region  46  of the substrate (see  FIGS. 1X and 2W ), and a second portion that extends up and over the floating gate  26  and down along the sides of the floating gate  26  (see  FIGS. 1W and 2W ). The oxide  24  and  34  in the silicon trenches provides isolation from the silicon fins and between adjacent memory cells. This cell configuration provides a split gate memory cell that combines (1) a control gate  36  having a first portion adjacent the floating gate  26  and a second portion that extends up and over the floating gate  26 , (2) a floating gate  26  that extends along the top surface and the side surfaces of a first portion of the fin shaped channel region  46  for enhanced capacitive coupling there between, (3) the first portion of the control gate  36  extends along the top surface and the side surfaces of a second portion of the fin shaped channel region  46 , which enhances capacitive coupling there between and maximizes current flow with smaller scaled device components (i.e. more device components within the same unit area of the substrate surface), (4) the second portion of the control gate  36  extends up and over the top portion of the floating gate, and extends out and over side portions of the floating gate, for enhanced capacitive coupling there between, and (5) the upper surface of the floating gate is sloping up to a sharpened edge  26   a  (relative to the floating gate sidewall) that faces the control gate  36  for enhanced tunneling there between. This configuration also allows for efficient formation processing with self-aligned memory cell components. 
         [0020]      FIG. 3  shows a top view of the memory cell array layout. Diffusing lines in the substrate connect rows of the source regions  42  together. The floating gates  26  are all self-aligned in the X direction by the photo resist  30  of  FIG. 20  and in the Y direction by the oxide spacers  18  of  FIG. 1F . Bit line contacts  48  are connected to the drain regions  44 , and are connected together in the Y direction by metal lines (not shown). 
         [0021]      FIG. 4  shows a top view of an alternate embodiment of the memory cell array layout, where rows of the source regions are connected together by source line contacts  36  and metal source lines  37  connecting those contacts together extending in the X direction, instead of lines of diffusion in the substrate. 
         [0022]      FIGS. 5A-5H  are side cross sectional views of an alternate embodiment in forming the Fin-FET split gate memory cell array. These figures show processing steps that can replace the processing steps described above with respect to  FIGS. 1A-1L and 2A-2L . This alternate processing defines the width of the semiconductor fins directly using lithography rather than by spacers. The process begins by forming a layer of oxide  52  on the silicon substrate  10  ( FIG. 5A ). A nitride layer  54  is formed on the oxide layer  52  ( FIG. 5B ). Photo resist  56  is deposited on the structure, followed by a photolithographic etch that leaves areas of the nitride layer  54  exposed ( FIG. 5C ). A nitride etch removes the exposed portions of the nitride layer  54  ( FIG. 5D ). The photoresist  56  is removed. An etch is used to remove exposed portions of the oxide layer  52  exposing the underlying substrate, and to remove exposed portions of substrate  10  to form trenches  58  into the exposed portions of the substrate  10  ( FIG. 5E ). Oxide is then deposited over the structure, followed by a chemical mechanical polish (CMP) using the nitride layer  54  as an etch stop, which fills the trenches with oxide  60  ( FIG. 5F ). A partial oxide etch is then performed to recess the oxide  60  in the trenches ( FIG. 5G ). A nitride etch is then used to remove the nitride  54 , and an oxide etch is used to remove the pad oxide  52  ( FIG. 5H ). The process continues then using the above described steps starting with those described with respect to  FIGS. 1M and 2M . 
         [0023]    It is to be understood that the present invention is not limited to the embodiment(s) described above and illustrated herein, but encompasses any and all variations falling within the scope of any claims supported thereby. For example, references to the present invention herein are not intended to limit the scope of any claim or claim term, but instead merely make reference to one or more features that may be covered by one or more claims. Materials, processes and numerical examples described above are exemplary only, and should not be deemed to limit any claims. Further, not all method steps need be performed in the exact order illustrated. Lastly, single layers of material could be formed as multiple layers of such or similar materials, and vice versa. 
         [0024]    It should be noted that, as used herein, the terms “over” and “on” both inclusively include “directly on” (no intermediate materials, elements or space disposed there between) and “indirectly on” (intermediate materials, elements or space disposed there between). Likewise, the term “adjacent” includes “directly adjacent” (no intermediate materials, elements or space disposed there between) and “indirectly adjacent” (intermediate materials, elements or space disposed there between), “mounted to” includes “directly mounted to” (no intermediate materials, elements or space disposed there between) and “indirectly mounted to” (intermediate materials, elements or spaced disposed there between), and “electrically coupled” includes “directly electrically coupled to” (no intermediate materials or elements there between that electrically connect the elements together) and “indirectly electrically coupled to” (intermediate materials or elements there between that electrically connect the elements together). For example, forming an element “over a substrate” can include forming the element directly on the substrate with no intermediate materials/elements there between, as well as forming the element indirectly on the substrate with one or more intermediate materials/elements there between.