Abstract:
A memory cell, device, system and method for operating a memory cell utilize an isolated dynamic cell plate. The memory cell includes a first and second pass transistor and a first and second capacitor. The first pass transistor and first capacitor and the second pass transistor and second capacitor are each configured in series for individual respective coupling between a first digit line and a second digit line. The first and second pass transistors are further configured for respective control by first and second wordlines. The memory cell further includes an interconnection formed on a cell plate conductor between a terminal end of the first capacitor and a terminal end of the second capacitor. Furthermore, the interconnection is electrically isolated from other portions of the cell plate conductor.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
       [0001]    This application is a continuation of U.S. patent application Ser. No. 11/653,590, filed Jan. 16, 2007, scheduled to issue as U.S. Pat. No. 7,684,228 on Mar. 23, 2010, which application is a continuation of U.S. patent application Ser. No. 11/212,987, filed Aug. 25, 2005, now U.S. Pat. No. 7,164,595, issued Jan. 16, 2007, the entire disclosure of each of which is hereby incorporated herein by this reference. 
     
    
     BACKGROUND OF THE INVENTION 
       [0002]    1. Field of the Invention 
         [0003]    The present invention relates generally to memory cells, arrays and devices and, in particular, to improvement of a refresh margin in a DRAM memory device. 
         [0004]    2. State of the Art 
         [0005]    Memory devices are typically provided as internal storage areas in a computer. There are several different types of memory, one of which is known as random access memory (RAM) that is typically used as main memory in a computer environment. Most RAM is volatile, meaning it requires a periodic regeneration of stored electrical charge to maintain its contents. A dynamic random access memory (DRAM) is a type of RAM that is made up of cells wherein each cell or bit includes one or more transistors and capacitors. A cell is capable of storing information in the form of a “1” or “0” bit as an electrical charge on the capacitor. Since a capacitor will lose its charge over time, a memory device incorporating a DRAM cell must include logic to refresh or recharge the capacitors of the cells on a periodic basis. Otherwise, the information stored therein will fade and be lost. One form of refreshing or recharging the capacitor is performed by reading the stored data in a memory cell and then writing the data back into the cell at a predefined voltage level, causing the information to be stored for a temporary period of time. 
         [0006]    More specifically, a conventional 2T DRAM array  10  shown in  FIG. 1  stores digital information in the form of “1” and “0” bits by storing the bits as electric charges on storage capacitors  38 ,  40  in a first memory cell and capacitors  48 ,  50  in a second memory cell as arranged along wordlines WL 0   56  and WL 1   58 . For clarity, a single 2T memory cell  20  is depicted in an upper portion of the array and is shown to include two capacitors (2C) and two transistors (2T) and is coupled to a sense amplifier  24  when isolation gates  30 ,  32  are activated by a sense amp isolation signal  26 . Furthermore, while DRAM array  10  is illustrated as including only eight memory cells in order to simplify description, the DRAM array  10  typically includes thousands or millions of memory cells. 
         [0007]    The DRAM array  10  stores a “1” bit in an exemplary memory cell, for example, the memory cell comprised of pass transistor  36 , storage capacitors  38 ,  40  and pass transistor  42 , by initially energizing the wordline WL 0   56  to activate the pass transistors  36 ,  42 . The DRAM array  10  then applies a “1” bit voltage equal to a supply voltage V cc  (e.g., 3.3 volts) to the true D 0  digit line  16 , causing current to flow from the digit line  16  via connection  54  through the activated pass transistor  36  and the storage capacitor  38  to a cell plate voltage  34 . As the current flows, the storage capacitor  38  stores positive electric charge received from the digit line  16 , causing a voltage on the storage capacitor  38  to increase. When the voltage on the storage capacitor  38  equals the “1” bit voltage on the digit line  16 , current stops flowing through the storage capacitor  38 . Similarly, energizing the wordline WL 0   56  also activates the pass transistor  42 . The DRAM array  10  then applies a “0” bit voltage equal to V ss  (e.g., 0 volts) to the complementary D 0 * digit line  18  causing current to flow from the cell plate voltage  34  to the storage capacitor  40 . As the current flows, the storage capacitor  40  stores positive electric charge received from the cell plate voltage  34 . A short time later, the DRAM array  10  deenergizes the wordline WL 0   56  to deactivate the pass transistors  36 ,  42  and isolate the storage capacitors  38 ,  40  from the digit lines  16 ,  18 , thereby preventing the positive electric charge stored on the storage capacitors  38 ,  40  from discharging back to the digit lines  16 ,  18 . 
         [0008]    Similarly, the DRAM array  10  stores a “0” bit in a memory cell, for example, by energizing the wordline WL 0   56  to activate the pass transistors  36 ,  42  and applies a “0” bit voltage approximately equal to a reference voltage V ss  (e.g., 0.0 volts) to the digit line  16 , causing current to flow from the cell plate voltage  34  to the storage capacitor  38  and the activated pass transistor  36  and to the true D 0  digit line  16 . As the current flows, storage capacitor  38  stores electric charge received from the cell plate voltage  34  causing the cell plate voltage  34  to be stored in a negative polarity in capacitor  38 . Similarly, the pass transistor  42  is also activated and causes the “1” bit voltage on complementary D 0 * digit line  18  to flow through pass transistor  42  and be stored in a negative polarity in storage capacitor  40 . The voltage stored across storage capacitor  40  is approximately equal to the supply voltage V cc  minus the cell plate voltage  34 . When the voltage across storage capacitors  38 ,  40  stabilizes, current stops flowing through the storage capacitors  38 ,  40  and a short time later the DRAM array  10  deenergizes the wordline WL 0   56  to deactivate the pass transistors  36 ,  42  and isolate the storage capacitors  38 ,  40  from the digit lines  16 ,  18 , thereby preventing the stored electrical charge on the storage capacitors  38 ,  40  from discharging back to the digit lines  16 ,  18 . 
         [0009]    The DRAM array  10  retrieves “1” and “0” bits stored in the manner described above in a memory cell by discharging the electric charges stored on the storage capacitors  38 ,  40  to the digit lines  16 ,  18  and then detecting a change in voltage on the digit lines  16 ,  18  resulting from the discharge with the sense amplifier  22  when isolation gates  30 ,  32  are activated by a sense amp isolation signal  26 . 
         [0010]    For example, the DRAM array  10  retrieves the “1” bit stored in the memory cell by first equilibrating the voltages on the digit lines  16 ,  18  to the cell plate voltage  34 . The DRAM array  10  then energizes the wordline WL 0   56  to activate the pass transistors  36 ,  42 , causing the positive electric charge stored on the storage capacitor  38  to discharge through the active pass transistor  36  and negative electrical charge stored on the storage capacitor  40  to discharge through the active pass transistor  42  to the digit lines  16 ,  18 . As a positive electric charge discharges, the voltage on the digit line  16  rises and the voltage on the digit line  18  decreases, causing a differential voltage between digit line  16  and digit line  18  as detected at sense amplifier  22 . When a differential voltage between the digit lines  16  and  18  exceeds a detection threshold of the sense amplifier  22 , the sense amplifier  22  responds by driving the voltage of the digit line  16  to the supply voltage V cc  and by driving the voltage on the digit line  18  approximately to the reference voltage V ss  and the detection of a “1” bit from the memory cell is completed. 
         [0011]    Likewise, the DRAM array  10  retrieves the “0” bit stored in the memory cell, for example, by first equilibrating the voltages on the digit lines  16  and  18  to the cell plate voltage  34 . The DRAM array  10  then energizes the wordline WL 0   56  to activate the pass transistors  36 ,  42  causing the negative electric charge stored in the storage capacitors  38 ,  40  to discharge through the activated pass transistors  36 ,  42  and positive electrical charge stored on the storage capacitor  40  to discharge through the active pass transistor  42  to the digit lines  16  and  18 . As the negative electric charge discharges, the voltage on the digit line  16  decreases below the cell plate voltage  34  and the voltage on digit line  18  increases above the cell plate voltage  34  causing a difference in voltages between digit lines  16  and  18  to exceed a detection threshold of the sense amplifier  22  causing the sense amplifier  22  to respond accordingly by driving the voltage on the digit lines  16 ,  18  to the appropriate voltages, namely, driving the voltage on digit line  16  to the reference voltage V ss  and the voltage on the digit line  18  to the supply voltage V cc . 
         [0012]    While an ideal configuration of a DRAM array has been described for storing and retrieving the logic states that were originally stored therein, DRAM arrays sometimes contain defective memory cells which cause the stored logic states to become undetectable or at least intermittently unreliable. In some instances, this occurs because the capacitance of the storage capacitors in these memory cells are too small, preventing the capacitors from retaining a sufficient electric charge to cause a change in the sensing voltage on the digit line when discharged to the digit line, such as in the case when the discharged voltage does not adequately influence the equilibrated digit lines in such a manner as to cause the sense amplifier&#39;s detection threshold to be reached. In other instances, memory arrays and their corresponding memory cells may be defective because the electric charge stored on the storage capacitors in such memory cells leaks away through a variety of mechanisms which also prevents the capacitors from retaining a sufficient electric charge to cause a detectable change in the threshold voltage on the digit lines when the storage capacitors are discharged to the digit lines. In either case, because the change in the sensed voltage caused by the discharging of the storage capacitors cannot be detected by the sense amplifier, the “1” and “0” bits represented by the electric charges stored in the memory cells are unretrievable. 
         [0013]    With respect to  FIG. 1 , the presence of a cell plate voltage  34  between the charges stored across storage capacitors  38  and  40  may deviate unequally if the cell plate voltage  34  is held to a constant voltage. For example, if a “1” bit is stored across a memory cell, a voltage potential approximately equal to V cc  minus the cell plate voltage  34  is stored across storage capacitor  38 . Similarly, a voltage of approximately the cell plate voltage  34  minus the reference voltage V ss  is stored across storage capacitor  40 . If storage capacitor  38  is defective and leaks a portion of the charge stored therein, the overall loss in stored charge is reflected only across the voltage as presented to digit line  16  during a sense operation. Accordingly, the charge coupled to digit line  16  during a sense operation may not be sufficient to exceed a sensing threshold during the sense operation. Similarly, any leakage on storage capacitor  40  would result solely in a change to the voltage as coupled to digit line  18  during a sense operation. Therefore, there is a need for an improved memory cell configuration for storing therein digit information that is less susceptible to a single defective storage capacitor. 
       BRIEF SUMMARY OF THE INVENTION 
       [0014]    The present invention, in exemplary embodiments, relates to a system and method using a dynamic cell plate in a memory cell. In one embodiment of the present invention, a memory cell includes a first and second portion with the first portion including a first pass transistor and a first capacitor coupled in series and configured for coupling in series between a first digit line at a port of the first pass transistor and a cell plate conductor at a terminal end of the first capacitor. The first pass transistor is further controlled by a first wordline. The second portion of the memory cell includes a second pass transistor and a second capacitor coupled in series and configured for coupling in series between a second digit line at a port of the second pass transistor and the cell plate conductor at a terminal end of the second capacitor. The second pass transistor is further controlled by a second wordline and the first and second portions are symmetrically configured with respect to each other. The memory cell further includes an interconnection formed on the cell plate conductor between the terminal end of the first capacitor and the terminal end of the second capacitor with the interconnection being electrically isolated from other portions of the cell plate conductor. 
         [0015]    In another embodiment of the present invention, a memory device is provided. The memory device includes a plurality of memory cells, wherein each of the memory cells includes a first and second pass transistor and a first and second capacitor. The first pass transistor and capacitor and the second pass transistor and capacitor are each configured in series for individual respective coupling between a first digit line and a second digit line. The first and second pass transistors are further configured for respective control by first and second wordlines. The first pass transistor and first capacitor are symmetrically configured with the second pass transistor and the second capacitor. The memory cell further includes an interconnection formed on a cell plate conductor between a terminal end of the first capacitor and a terminal end of the second capacitor. Furthermore, the interconnection is electrically isolated from other portions of the cell plate conductor. The memory device further includes a plurality of sense amplifiers configured for selectably coupling with pairs of the first and second digit lines. 
         [0016]    In a further embodiment of the present invention, a semiconductor wafer is provided. The semiconductor wafer includes an integrated circuit configured as a memory array wherein the memory array includes a plurality of memory cells. Each of the memory cells includes first and second pass transistors and first and second capacitors with the first pass transistor and first capacitor and the second pass transistor and second capacitor each being configured in series for individual respective coupling between a first digit line and a second digit line. The first and second pass transistors are further configured for respective control by first and second wordlines. In the memory cell, the first pass transistor and first capacitor are symmetrically configured with the second pass transistor and second capacitor. The memory cell further includes an interconnection formed on a cell plate conductor between a terminal end of the first capacitor and a terminal end of the second capacitor. Furthermore, the interconnection is electrically isolated from other portions of the cell plate conductor. 
         [0017]    In yet another embodiment of the present invention, an electronic system is provided. The electronic system includes an input device, an output device, a memory device, and a processor device coupled to the input, output and memory devices. The memory device comprises a memory array including a plurality of memory cells, wherein each of the memory cells includes a first and second pass transistor and a first and second capacitor. The first pass transistor and capacitor and the second pass transistor and capacitor are each configured in series for individual respective coupling between a first digit line and a second digit line. The first and second pass transistors are further configured for respective control by first and second wordlines and the first pass transistor and capacitor are symmetrically configured with the second pass transistor and capacitor. The memory cell further includes an interconnection formed on a cell plate conductor between a terminal end of the first capacitor and a terminal end of the second capacitor. Furthermore, the interconnection is electrically isolated from other portions of the cell plate conductor. 
         [0018]    In yet a further embodiment of the present invention, a method of operating a memory array is provided. A series configured symmetrical first and second capacitors are charged to a logic potential through opposing series configured first and second pass transistors respectively coupled to first and second digit lines. The first and second digit lines are pre-charged to an intermediate reference. The logic potential of the first and second capacitors are discharged through the first and second pass transistors coupled to the first and second digit lines. At least a portion of the logic potential is sensed on the first and second digit lines to determine a logic state. 
     
    
     
       BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS 
         [0019]    In the drawings, which illustrate what is currently considered to be the best mode for carrying out the invention: 
           [0020]      FIG. 1  is a schematic diagram of a conventional dynamic random access memory; 
           [0021]      FIG. 2  is a plan view diagram of a dynamic cell plate of a memory cell, in accordance with an embodiment of the present invention; 
           [0022]      FIG. 3  is a schematic diagram of a dynamic random access memory array, in accordance with an embodiment of the present invention; 
           [0023]      FIG. 4  is a schematic diagram of a dynamic random access memory array, in accordance with another embodiment of the present invention; 
           [0024]      FIG. 5  is a schematic diagram of a dynamic random access memory array, in accordance with a further embodiment of the present invention; 
           [0025]      FIG. 6  is a schematic diagram of a dynamic random access memory array, in accordance with yet another embodiment of the present invention; 
           [0026]      FIG. 7  is a block diagram of a memory device, in accordance with an embodiment of the present invention; 
           [0027]      FIG. 8  is a block diagram of an electronic system, in accordance with an embodiment of the present invention; and 
           [0028]      FIG. 9  is a diagram of a semiconductor wafer including an integrated circuit die incorporating a memory cell of one or more of the previous embodiments, in accordance with a further embodiment of the present invention. 
       
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       [0029]    In the following detailed description of the preferred embodiments, reference is made to the accompanying drawings, which form a part hereof, and in which is shown by way of illustration specific preferred embodiments in which the inventions may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention, and it is to be understood that other embodiments may be utilized and that logical, mechanical and electrical changes may be made without departing from the spirit and scope of the present invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is defined by the claims and equivalents thereof 
         [0030]    It is noted that the term “pass transistor” as used herein implies a gated device that includes two ports or I/O that are coupled together through control of a gate input. Additionally, the term “capacitor” as used herein implies an information retention device whether through energy storage, structural orientation and reorientation, or otherwise. 
         [0031]    As used herein the term “refresh margin” relates to the amounts of time that a memory cell is capable of retaining an adequate quantity of charge for accurately representing a logic state. Once the refresh margin is exceeded prior to refreshing the memory cell, the discerned logic states become unreliable. 
         [0032]    A plan view of a portion of a DRAM memory array in accordance with the present invention is illustrated in  FIG. 2 .  FIG. 2  illustrates an exemplary layout of a specific feature dimension, however, the present figure is illustrative and not to be considered as limiting. In this example of a DRAM memory array layout, cells are paired to share a common contact to the digit line (DL), which reduces the array size by eliminating duplication. This layout is arranged in an open digit line architecture wherein each half of memory cell  80 , one half of which is shown as half  98  and another half of which is shown as half  101 , has an area equal to 6F 2 . That is, the area of a memory cell  80  in this layout is described as 12F 2 . As illustrated in  FIG. 2 , a box is drawn around a memory cell  80  to show the cell&#39;s outer boundary. In the present embodiment, a conventional 6F 2  memory cell process configured to include a 1T-1C memory cell architecture couples an adjacent one of a 1T-1C memory cell together through the modification of a single processing layer to form a 2T-2C memory cell without subjecting the 6F 2  process to further modifications. The benefits of a 2T-2C architecture are manifest in an extended refresh margin by utilizing a dynamic cell plate reference to each of the capacitors in the 2T-2C architecture. Therefore, variations in a static cell plate voltage and significant leakage in a single capacitor may be minimized by the presence of a dynamic cell plate reference local to each memory cell. 
         [0033]    By way of example,  FIG. 2  illustrates the dimensioning of a 6F 2  process for the formation of the one half  98  of the dynamic cell plate 2T-2C memory cell  80 , in accordance with an embodiment of the present invention. As illustrated, along the horizontal axis of the one half  98  of memory cell  80 , the box includes one-half digit line contact feature  102 , one wordline feature  104 , one capacitor feature  106 , illustrated as a stacked capacitor, and one-half field oxide feature  108  for a total of three features. Along the vertical axis of the one half  98  of memory cell  80 , the box contains two one-half field oxide features  112 ,  114  and one active area feature  110  for a total of two features. Therefore, the total area of one half  98  of the memory cell  80  is 3F*2F=6F 2 . Moreover, as  FIG. 2  illustrates, the halves  98 ,  101  of a memory cell  80  are adjacent and connectable through isolated and an individual capacitor pair interconnect  84 , which releases the memory cell  80  from being configured as a static cell plate memory cell and is thereafter configured as a dynamic cell plate memory cell  80 . This is accomplished, in this example, by altering a mask layer of a 6F 2  process for a 1T-1C memory cell process. A discussion of DRAM circuit design including open digit line architecture is provided in Brent Keeth and Jacob Baker,  DRAM Circuit Design, A Tutorial,  1-103 (IEEE Press 2001), which is incorporated herein by reference. 
         [0034]    Referring to  FIG. 3 , a schematic diagram of a memory array  100  according to the present invention including a 1T-1C 6F 2  portion of a memory cell of an open digit line DRAM array is illustrated, wherein the 2T-2C memory cells have an area of 12F 2 . For clarity, a single memory cell  120  is depicted in an upper portion of the array and is shown to include two capacitors (2C) and two transistors (2T) and is coupled to a sense amplifier  124  when isolation gates  130 ,  132  are activated by a sense amp isolation signal  126 . 
         [0035]    As illustrated, a sense amplifier  122  is coupled between digit line D 1   116  and complementary digit line D 1 *  118  when isolation gates  130 ,  132  are activated by a sense amp isolation signal  126  and another sense amplifier  124  is coupled between digit line D 0   170  and complementary digit line D 0 *  172  when isolation gates  130 ,  132  are activated by a sense amp isolation signal  126 . Cells with a “1” bit can be expressed as having a +(Vcc−Vss)/2 stored on each capacitor  138  and  140  and cells with a “0” bit can be expressed as having a −(Vcc−Vss)/2 stored on capacitors  138  and  140 . To read a memory cell, a digit line coupled to the cell and its complementary digit line are first initially equilibrated to Vcc/2 volts. Applying Vcc/2 bias voltage to the digit lines and then allowing the digit lines to float causes the digit lines to be equilibrated to Vcc/2 volts. Once the digit lines have been equilibrated to Vcc/2 volts, they remain in that state due to their capacitance. The equilibration of the digits is deactivated immediately before activating the wordline ensuring that the digits are floating when the cells and digits charge share. A voltage that is at least one transistor Vth above Vcc (this voltage is referred to as Vccp) is then applied to a wordline coupled to the cell to be read. For example, if memory cell M 1   180  is to be read, a voltage of Vccp is applied to wordline WL 0   156  to activate pass transistors  136 ,  142  after the digit lines D 1   116  and D 1 *  118  are equilibrated to Vcc/2. The charge on the capacitors of memory cell M 1   180  is shared with digit line D 1   116 . In response to the shared charge, the voltage on the digit line of memory cell M 1   180  either increases if memory cell M 1   180  stored a 1-bit, or decreases if memory cell M 1   180  stored a 0-bit. Thereafter, sense amplifier  122  compares the voltage in digit line D 1   116  against the voltage in digit line D 1 *  118 . Because of the shared buried contacts  144 ,  154 , operation of memory cell M 2   182  occurs similarly through the activation of wordline WL 1   158  and the coupling of charge from capacitors  148 ,  150  with digit line D 1   116  and digit line D 1 *  118  through pass transistors  146 ,  152 . 
         [0036]    In the various embodiments of the present invention, the refresh margin may be improved through processing a memory cell that is not statically bound to a fixed cell plate voltage, but is processed to include a dynamic cell plate node that is not fixed to a static voltage. In a memory cell architecture that includes a 2T (two transistor) memory cell, a common node or common capacitor interconnect  184  connects or associates the 2C (two capacitors) of memory cell M 1   180  with each other by isolating the cell plate node from an otherwise continuous cell plate conductor or cell plate node layer that conventionally couples to each of the memory cells in a conventional memory array. In the various embodiments of the present invention, improvements in refresh margin may be obtained by modification to the continuous cell plate node layer by forming the common capacitor interconnects  184 ,  186  from individual isolated conductive islands in the continuous cell plate node layer that electrically couples the storage capacitors in a series configuration without further connecting the common node to a static cell plate voltage. 
         [0037]    Referring to  FIG. 4 , a schematic diagram of a memory array  200  according to one embodiment of the present invention including a 6F 2  portion of a memory cell of an open digit line DRAM array is illustrated, in accordance with another embodiment of the present invention, wherein the 2T-1C memory cells have an area of 12F 2 . For clarity, a single memory cell  220  is depicted in an upper portion of the array and is shown to include one capacitor (1C) and two transistors (2T) and is coupled to a sense amplifier  224  when isolation gates  230 ,  232  are activated by a sense amp isolation signal  226 . 
         [0038]    As illustrated, a sense amplifier  222  is coupled between digit line D 1   216  and complementary digit line D 1 *  218  when isolation gates  230 ,  232  are activated by a sense amp isolation signal  226  and another sense amplifier  224  is coupled between digit line D 0   270  and complementary digit line D 0 *  272  when isolation gates  230 ,  232  are activated by a sense amp isolation signal  226 . Cells with a “1” bit can be expressed as having a +(Vcc−Vss) stored on the capacitor  238  (illustrated as a common capacitor) and cells with a “0” bit can be expressed as having a −(Vcc−Vss) stored on the capacitor  238 . To read a memory cell, a digit line coupled to the cell and its complementary digit line are first initially equilibrated to Vcc/2 volts. Applying Vcc/2 bias voltage to the digit lines and then allowing the digit lines to float causes the digit lines to be equilibrated to Vcc/2 volts. Once the digit lines have been equilibrated to Vcc/2 volts, they remain in that state due to their capacitance. A voltage that is at least one transistor Vth above Vcc (this voltage is referred to as Vccp) is then applied to a wordline coupled to the cell to be read. For example, if memory cell M 1   280  is to be read, a voltage of Vccp is applied to wordline WL 0   256  to activate pass transistors  236 ,  242  after the digit lines D 1   216  and D 1 *  218  are equilibrated to Vcc/2. The charge on the capacitor of memory cell M 1   280  is shared with digit line D 1   216 . In response to the shared charge, the voltage on the digit line of memory cell M 1   280  either increases if memory cell M 1   280  stored a 1-bit, or decreases if memory cell M 1   280  stored a 0-bit. Thereafter, sense amplifier  222  compares the voltage in digit line D 1   216  against the voltage in digit line D 1 *  218 . Because of shared buried contacts  244 ,  254 , operation of memory cell M 2   282  occurs similarly through the activation of wordline WL 1   258  and the coupling of charge from capacitor  248  with digit line D 1   216  and digit line D 1 *  218  through pass transistors  246 ,  252 . 
         [0039]    In the present embodiment of the invention, the refresh margin may be improved through processing a memory cell that is not statically bound to a fixed cell plate voltage but is processed to include a dynamic cell plate node that is not fixed to a static voltage. In a memory cell architecture that includes a 2T (two transistor) memory cell M 1   280 , a common capacitor  238  connects and isolates the cell plate node from an otherwise continuous cell plate node layer that conventionally couples to each of the memory cells in a conventional memory array. In the various embodiments of the present invention, improvements in refresh margin may be obtained by modification to the otherwise continuous cell plate node layer by forming the common capacitor  238  without further connecting to a static cell plate voltage. 
         [0040]    Referring to  FIG. 5 , a schematic diagram of a memory array  300  according to one embodiment of the present invention including a 1T-1C 8F 2  portion of a memory cell of an open digit line DRAM array is illustrated, wherein the 2T-2C memory cells have an area of 16F 2 . For clarity, a single memory cell  320  is depicted in an upper portion of the array and is shown to include two capacitors (2C) and two transistors (2T) and is coupled to a sense amplifier  324  when isolation gates  330 ,  332  are activated by a sense amp isolation signal  326 . 
         [0041]    As illustrated, a sense amplifier  322  is coupled between digit line D 1   316  and complementary digit line D 1 *  318  when isolation gates  330 ,  332  are activated by a sense amp isolation signal  326  and another sense amplifier  324  is coupled between digit line D 0   370  and complementary digit line D 0 *  372  when isolation gates  330 ,  332  are activated by a sense amp isolation signal  326 . Cells with a “1” bit can be expressed as having a +(Vcc−Vss)/2 stored on each capacitor  338  and  340  and cells with a “0” bit can be expressed as having a −(Vcc−Vss)/2 stored on capacitors  338  and  340 . To read a memory cell, a digit line coupled to the cell and its complementary digit line are first initially equilibrated to Vcc/2 volts. Applying Vcc/2 bias voltage to the digit lines and then allowing the digit lines to float causes the digit lines to be equilibrated to Vcc/2 volts. Once the digit lines have been equilibrated to Vcc/2 volts, they remain in that state due to their capacitance. A voltage that is at least one transistor Vth above Vcc (this voltage is referred to as Vccp) is then applied to a wordline coupled to the cell to be read. For example, if cell M 1   380  is to be read, a voltage of Vccp is applied to wordline WL 0   356 ,  358  to activate the pass transistors  336 ,  342  after the digit lines D 1   316  and D 1 *  318  are equilibrated to Vcc/2. The charge on the capacitors of memory cell M 1   380  is shared with digit line D 1   316 . In response to the shared charge, the voltage on the digit line of memory cell M 1   380  either increases if memory cell M 1   380  stored a 1-bit, or decreases if memory cell M 1   380  stored a 0-bit. Thereafter, sense amplifier  322  compares the voltage in digit line D 1   316  against the voltage in digit line D 1 *  318 . Because of shared buried contacts  344 ,  354 , operation of memory cell M 2   382  occurs similarly through the activation of wordline WL 1   360 ,  362  and the coupling of charge from capacitors  348 ,  350  with digit line D 1   316  and digit line D 1 *  318  through pass transistors  346 ,  352 . 
         [0042]    In the present embodiment of the invention, the refresh margin may be improved through processing a memory cell that is not statically bound to a fixed cell plate voltage but is processed to include a dynamic cell plate node that is not fixed to a static voltage. In a memory cell architecture that includes a 2T (two transistor) memory cell, a common node or common capacitor interconnect  384  connects or associates the 2C (two capacitors) of memory cell M 1   380  with each other by isolating the cell plate node from an otherwise continuous cell plate conductor or cell plate node layer that conventionally couples to each of the memory cells in a conventional memory array. In the various embodiments of the present invention, improvements in refresh margin may be obtained by modification to the continuous cell plate node layer by forming common capacitor interconnects  384 ,  386  from individual isolated conductive islands in the otherwise continuous cell plate node layer that electrically couples the storage capacitors in a series configuration without further connecting the common node to a static cell plate voltage. 
         [0043]    Referring to  FIG. 6 , a schematic diagram of a memory array  400  according to one embodiment of the present invention including a portion of a memory cell of an open digit line DRAM array is illustrated, wherein the 2T-1C memory cells have an area of 16F 2 . For clarity, a single memory cell  420  is depicted in an upper portion of the array and is shown to include one capacitor (1C) and two transistors (2T) and is coupled to a sense amplifier  424  when isolation gates  430 ,  432  are activated by a sense amp isolation signal  426 . 
         [0044]    As illustrated, a sense amplifier  422  is coupled between digit line D 1   416  and complementary digit line D 1 *  418  when isolation gates  430 ,  432  are activated by a sense amp isolation signal  426  and another sense amplifier  424  is coupled between digit line D 0   470  and complementary digit line D 0 *  472  when isolation gates  430 ,  432  are activated by a sense amp isolation signal  426 . Cells with a “1” bit can be expressed as having a +(Vcc−Vss)/2 stored on the capacitor  438  and cells with a “0” bit can be expressed as having a −(Vcc−Vss)/2 stored on the capacitor  438 . To read a memory cell, a digit line coupled to the cell and its complementary digit line are first initially equilibrated to Vcc/2 volts. Applying Vcc/2 bias voltage to the digit lines and then allowing the digit lines to float causes the digit lines to be equilibrated to Vcc/2 volts. Once the digit lines have been equilibrated to Vcc/2 volts, they remain in that state due to their capacitance. A voltage that is at least one transistor Vth above Vcc (this voltage is referred to as Vccp) is then applied to a wordline coupled to the cell to be read. For example, if memory cell M 1   480  is to be read, a voltage of Vccp is applied to wordline WL 0   456 ,  458  to activate the pass transistors  436 ,  442  after the digit lines D 1   416  and D 1 *  418  are equilibrated to Vcc/2. The charge on the capacitor of memory cell M 1   480  is shared with digit line D 1   416 . In response to the shared charge, the voltage on the digit line of memory cell M 1   480  either increases if memory cell M 1   480  stored a 1-bit, or decreases if memory cell M 1   480  stored a 0-bit. Thereafter, sense amplifier  422  compares the voltage in digit line D 1   416  against the voltage in digit line D 1 *  418 . Because of the shared buried contacts  444 ,  454 , operation of memory cell M 2   482  occurs similarly through the activation of wordline WL 1   460 ,  462  and the coupling of charge from capacitor  448  with digit line D 1   416  and digit line D 1 *  418  through pass transistors  446 ,  452 . 
         [0045]    In the present embodiment of the invention, the refresh margin may be improved through processing a memory cell that is not statically bound to a fixed cell plate voltage but is processed to include a dynamic cell plate node that is not fixed to a static voltage. In a memory cell architecture that includes a 2T (two transistor) memory cell M 1   480 , a common capacitor  438  connects and isolates the cell plate node from an otherwise continuous cell plate node layer that conventionally couples to each of the memory cells in a conventional memory array. In the various embodiments of the present invention, improvements in refresh margin may be obtained by modification to the otherwise continuous cell plate node layer by forming the common capacitor  438  without further connecting to a static cell plate voltage. 
         [0046]      FIG. 7  is a block diagram of a memory device and system, in accordance with an embodiment of the present invention. A DRAM memory device  500  includes control logic circuit  520  to control read, write, erase and perform other memory operations. A column address buffer  524  and a row address buffer  528  are adapted to receive memory address requests. A refresh controller/counter  526  is coupled to the row address buffer  528  to control the refresh of memory array  522 . A row decode circuit  530  is coupled between the row address buffer  528  and the memory array  522 . A column decode circuit  532  is coupled to the column address buffer  524 . Sense amplifiers-I/O gating circuit  534  is coupled between the column decode circuit  532  and the memory array  522 . The DRAM memory device  500  is also illustrated as having an output buffer  536  and an input buffer  538 . An external processor  540  is coupled to the control logic circuit  520  of the DRAM memory device  500  to provide external commands. 
         [0047]    A memory cell M 1   550  of the memory array  522  is shown in  FIG. 7  to illustrate how associated memory cells are implemented in the present invention. States or charge are stored in the memory cell M 1   550  that correspond to a data bit. A wordline WL 0   542  is coupled to the gates of the memory cell M 1   550 . When the wordline WL 0   542  is activated, the charge stored in memory cell M 1   550  is discharged to digit lines DL 0   552  and DL 0 *  554 . Digit line DL 0   552  and digit line DL 0 *  554  are coupled to a sense amplifier in circuit  534 . Although the memory cell M 1   550  is illustrated as being coupled to one wordline WL 0   542  in  FIG. 7 , it will be appreciated by those in the art that a pair of wordlines (i.e., WL 0  and WL 1 ) that are fired at the same time (e.g., memory cell of  FIGS. 5 and 6 ) could be used, and the present invention is not limited to one wordline for each memory cell. 
         [0048]      FIG. 8  is a block diagram of an electronic system, in accordance with an embodiment of the present invention. The electronic system  600  includes an input device  672 , an output device  674 , and a memory device  678 , all coupled to a processor device  676 . The memory device  678  incorporates at least one memory cell  640  of one or more of the preceding embodiments of the present invention. 
         [0049]      FIG. 9  is a diagram of a semiconductor wafer including an integrated circuit die incorporating the memory array of one or more of the previous embodiments, in accordance with a further embodiment of the present invention. As shown in  FIG. 9 , a semiconductor wafer  700  includes a yet-to-be-cut integrated circuit die  740  that incorporates one or more memory cells as herein disclosed. 
         [0050]    The various embodiments of the present invention as described herein provide for an improved refresh margin by applying a dynamic cell plate to a 2T architecture memory cell. Instead of a common cell plate node connected to a voltage generator, each pair of pass transistors and one or more storage capacitors associated to a given address or memory cell/bit has a floating isolated cell node which connects to the capacitive elements. In a conventional memory cell layout, changes to processing may be minimized and result in as little as a single layer change in a conventional or typical DRAM process. While additional embodiments have been disclosed which include a single capacitive element, such process alterations are also minimized but may incur more deviations from a standard or typical DRAM process than with a dual or two capacitor memory cell. 
         [0051]    Although specific embodiments have been illustrated and described herein, it will be appreciated by those of ordinary skill in the art that any arrangement calculated to achieve the same purpose may be substituted for the specific embodiments shown. This application is intended to cover any adaptations or variations of the present invention. Therefore, it is manifestly intended that this invention be limited only by the claims and the equivalents thereof.