FIELD OF THE INVENTION
The exemplary embodiments of the present invention relate generally to the field of memory, and more specifically to memory cells and array structures and associated processes.
BACKGROUND OF THE INVENTION
With the increasing complexity and density of electronic circuits, memory size, complexity, and cost are important considerations. One approach to increase memory capacity is to use three-dimensional (3D) array structure. The 3D array structure has been successfully used in NAND flash memory today. However, for dynamic random-access memory (DRAM), due to its special one-transistor-one-capacitor (1T1C) cell structure, a cost-effective 3D array structure has not been realized.
SUMMARY
In various exemplary embodiments, three-dimensional (3D) memory cells, array structures, and associated processes are disclosed. In one embodiment, a novel 3D array structure using floating-body cells to implement DRAM is disclosed. The array structure is formed using a deep trench process similar to 3D NAND flash memory. Therefore, ultra-high-density DRAM can be realized. In one embodiment, 3D NOR-type memory cells and array structures are provided. The disclosed memory cells and array structures are applicable to many technologies. For example, the inventive memory cells and array structures are applicable to dynamic random-access memory (DRAM), floating-body cell (FBC) memory, NOR-type flash memory, and thyristors.
In an exemplary embodiment, a memory cell structure is provided that includes a first semiconductor material, a floating body semiconductor material having an internal side surface that surrounds and connects to the first semiconductor material, and a second semiconductor material having an internal side surface that surrounds and connects to the floating body semiconductor material. The memory cell structure also includes a first dielectric layer connected to a top surface of the floating body material, a second dielectric layer connected to a bottom surface of the floating body material, a front gate connected to the first dielectric layer, and a back gate connected to the second dielectric layer.
In an exemplary embodiment, a three-dimensional (3D) memory array is provided that comprises a plurality of memory cells separated by a dielectric layer to form a stack of memory cells. Each memory cell in the stack of memory cells comprises a bit line formed from one of a first semiconductor material and a first conductor material, a floating body semiconductor material having an internal side surface that surrounds and connects to the bit line, a source line formed from one of a second semiconductor material and a second conductor material having an internal side surface that surrounds and connects to the floating body semiconductor material, and a word line formed from a third conductor material that is coupled to the floating body semiconductor through the dielectric layer to form a gate of the memory cell. Additionally, the bit lines of the stack of memory cells are connected to form a vertical bit line.
Additional features and benefits of the exemplary embodiments of the present invention will become apparent from the detailed description, figures and claims set forth below.
BRIEF DESCRIPTION OF THE DRAWINGS
The exemplary embodiments of the present invention will be understood more fully from the detailed description given below and from the accompanying drawings of various embodiments of the invention, which, however, should not be taken to limit the invention to the specific embodiments, but are for explanation and understanding only.
FIG. 1A show an exemplary embodiment of a three-dimensional (3D) NOR-type memory cell structure using a floating body cell (FBC) configuration in accordance with the invention.
FIG. 1B shows the cell structure shown in FIG. 1A with a front gate and a gate dielectric layer removed.
FIG. 1C shows a cell formed using a PMOS transistor.
FIG. 1D shows an embodiment of an array structure based on the cell structure shown in FIG. 1A.
FIG. 1E shows another embodiment of an array structure according to the invention.
FIG. 1F shows an equivalent circuit diagram for the array structure shown in FIG. 1D.
FIG. 1G shows another embodiment of an equivalent circuit diagram of the array structure shown in FIG. 1D.
FIGS. 1H-I show embodiments of a junction-less transistor cell structure according to the invention.
FIGS. 1J-K show embodiments of a tunnel field-effect transistor (T-FET) cell structure according to the invention.
FIG. 1L shows another embodiment of the cell structure according to the invention that uses a metal bit line and source line.
FIG. 1M shows embodiments of a thin-film structure and an indium-gallium-zinc-oxide (IGZO) transistor cell structure according to the invention
FIG. 2A shows an embodiment of a write data ‘1’ condition of the cell according to the invention.
FIG. 2B shows another embodiment of a write data ‘1’ condition of the cell according to the invention.
FIG. 2C shows an embodiment of a write data ‘0’ condition of the cell according to the invention.
FIG. 2D shows an exemplary waveform of the write data ‘0’ condition according to the invention.
FIG. 3A shows a threshold voltage (Vt) of the cell data ‘0’ and data ‘1’.
FIG. 3B shows how a threshold voltage of the cell transistors to become negative.
FIG. 3C shows a special read condition to address issues illustrated in FIG. 3B.
FIG. 3D shows a table that summarizes the bias conditions of write data ‘1’, write data ‘0’, and read operations.
FIGS. 4A-F show simplified process steps for constructing the array structure shown in FIG. 3.
FIGS. 4G-H show additional embodiments of array structures according to the invention.
FIGS. 4I-J show another embodiment of process steps to form the body of the transistors.
FIG. 4K shows an embodiment of the bit line connection of the array structure shown in FIG. 4F.
FIG. 4L shows another embodiment of the array structure according to the invention to solve the previously mentioned issue with using many word line decoders.
FIG. 4M shows the bit line connections of the array embodiment shown in FIG. 4L.
FIG. 4N shows another embodiment of an array architecture according to the invention.
FIG. 4O shows an embodiment of a non-volatile program operation to write data stored in floating bodies and to a charge-trapping layer.
FIG. 4P shows another embodiment of a 3D floating body cell array structure according to the invention.
FIG. 4Q shows a write ‘0’ condition of the array structure embodiment shown in FIG. 4P.
FIG. 4R shows an embodiment of write ‘0’ waveforms.
FIG. 4S shows bias conditions of write data ‘1’, write data ‘0’, and read operations for the array embodiment shown in FIG. 4P.
FIGS. 4T-Z show an embodiment of process steps to form the cell array structure shown in FIG. 4P.
FIG. 5A shows another embodiment of a cell structure according to the invention.
FIG. 5B shows the cell structure of FIG. 5A with a front gate and a gate dielectric layer removed.
FIGS. 5C-D show another embodiment of a cell structure according to the invention.
FIG. 6A shows another embodiment of a cell structure according to the invention.
FIG. 6B shows the cell structure shown in FIG. 6A with a front gate and gate dielectric layer removed.
FIGS. 6C-D show another embodiment of a cell structure according to the invention.
FIG. 7 shows an embodiment of an array structure based on the cell structure shown in FIG. 6A.
FIGS. 8A-F show simplified process steps for forming the array structure shown in FIG. 7.
FIG. 9A shows another embodiment of a cell structure according to the invention.
FIG. 9B shows an embodiment of an array structure based on the cell structure shown in FIG. 9A.
FIGS. 10A-D show simplified process steps for constructing the cell structure shown in FIG. 9A.
FIG. 11A shows another embodiment of a cell structure according to the invention.
FIG. 11B shows an embodiment of an array structure based on the cell structure shown in FIG. 11A.
FIGS. 12A-D shows simplified process steps for constructing the cell structure shown in FIG. 11A.
FIG. 13A shows another embodiment of a DRAM-replacement technology according to the invention.
FIG. 13B shows the cell structure of FIG. 13A with a front gate and a gate dielectric layer removed.
FIG. 13C shows another embodiment of a 3D thyristor cell structure according to the invention.
FIG. 14A shows a circuit diagram in which two bipolar transistors form a gate-assisted thyristor cell.
FIG. 14B shows a circuit diagram that forms a non-gate-assisted thyristor cell.
FIG. 14C shows a current to voltage (I-V) curve of the thyristor cell shown in FIG. 13A.
FIG. 15A shows an embodiment of a 3D array structure based on the cell structure shown in FIG. 13A.
FIG. 15B shows an embodiment of a 3D array structure based on the cell structure shown in FIG. 13C.
FIG. 16A shows another embodiment of a thyristor cell structure according to the invention.
FIG. 16B shows the cell structure shown in FIG. 16A with a front gate and a gate dielectric layer removed.
FIG. 16C shows another embodiment of a thyristor cell structure according to the invention.
FIG. 17A shows an embodiment of a 3D array structure based on the cell structure shown in FIG. 16A.
FIG. 17B shows an embodiment of a 3D array structure based on the cell structure shown in FIG. 16C.
FIG. 18A shows another embodiment of a thyristor cell structure according to the invention.
FIG. 18B shows an embodiment of a 3D array structure based on the cell structure shown in FIG. 16C.
FIG. 19A shows another embodiment of a 3D array structure according to the invention that uses ‘tunnel field-effect transistor (TFET)’ technology.
FIG. 19B shows a cross-section of the array structure shown in FIG. 19A that is taken at cross-section indicator A-A’ to reveal the structure of an insulating layer.
FIG. 20A shows a vertical cross section view of the 3D array structure shown in FIG. 19A.
FIG. 20B shows another embodiment of the vertical cross section view of the 3D array structure shown in FIG. 19A.
FIG. 20C shows another embodiment of the vertical cross section view of the 3D array structure according to the invention.
FIG. 21A shows another embodiment of the 3D array structure according to the invention.
FIG. 21B shows another embodiment of the 3D array structure according to the invention.
FIG. 21C shows another embodiment of a 3D array structure according to the invention.
FIG. 21D shows another embodiment of a 3D array structure according to the invention.
FIG. 22A shows another embodiment of a 3D cell structure according to the invention.
FIG. 22B shows an inner structure of the 3D cell structure shown in FIG. 22A.
FIG. 23A shows another embodiment of a 3D cell structure according to the invention.
FIG. 23B shows the inner structure of the 3D cell structure shown in FIG. 23A.
FIG. 24A shows another embodiment of the 3D cell structure according to the invention.
FIG. 24B shows the inner structure of the 3D cell structure shown in FIG. 24A.
FIG. 25A shows another embodiment of 3D cell structure according to the invention.
FIG. 25B shows an inner structure of the 3D cell structure shown in FIG. 25A.
FIGS. 26A-G shows simplified key process steps of another embodiment of a floating body cell “AND” array according to the invention.
DETAILED DESCRIPTION
Those of ordinary skilled in the art will realize that the following detailed description is illustrative only and is not intended to be in any way limiting. Other embodiments of the present invention will readily suggest themselves to skilled persons having the benefit of this disclosure. Reference will now be made in detail to implementations of the exemplary embodiments of the present invention as illustrated in the accompanying drawings. The same reference indicators or numbers will be used throughout the drawings and the following detailed description to refer to the same or like parts.
In various exemplary embodiments, three-dimensional (3D) memory cells, array structures, and associated processes are disclosed. The disclosed memory cells and array structures are applicable to many technologies. For example, the inventive memory cells and array structures are applicable to dynamic random-access memory (DRAM), floating-body cell (FBC) memory, NOR-type flash memory, and thyristors.
FIG. 1A show an exemplary embodiment of a three-dimensional (3D) NOR-type memory cell structure using a floating body cell (FBC) configuration in accordance with the invention. The 3D NOR-type array may comprise multiple layers of floating-body cell arrays to increase the memory capacity. A floating-body cell is basically a transistor with floating body. The floating body may store electric charges such as electrons or holes to represent the data. The cell structure may comprise a control gate, a drain, a source, and a floating body. In the 3D memory array, the control gate, drain, and source of the cells are connected to word line (WL), bit line (BL), and source line (SL), respectively.
In the cell structure, an N+ silicon or polysilicon forms a bit line (BL) 101 and a P- floating body 102 is used for charge storage. An N+ silicon or polysilicon forms a source line (SL) 103. The cell may be formed as a dual-gate transistor shown in FIG. 1A or a single-gate transistor shown in FIG. 1B. For the dual-gate transistor shown in FIG. 1A, the cell structure comprises two control gates called a front gate 104a and a back gate 104b, respectively. Both the front gate 104a and the back gate 104b are coupled to the floating body 102 through gate dielectric layers 105a and 105b, respectively. The gate dielectric layer is an insulating layer between the gate and the body of the transistor. When a proper voltage is applied to the front gate 104a or the back gate 104b, a front gate channel (FGC) 1014 or a back gate channel (BGC) 1012 are formed in the surface of the floating body 102 under the gate dielectric layer 105a and 105b to conduct current between the bit line 101 and source line 103. In an embodiment, the front gate 104a and back gate 104b are connected to different word lines (WL).
In an embodiment, the P- floating body 102 comprises multiple surfaces as shown in FIG. 1A. An internal side surface 1002 surrounds and connects to the BL 101. An external side surface 1004 connects to the source line 103. A top surface 1008 connects to the dielectric layer 105a, and a bottom surface 1006 connects to the dielectric layer 105b. Thus, in one embodiment, a memory cell structure is provided that includes a first semiconductor material BL 101, a floating body semiconductor material 102 having an internal side surface 1002 that surrounds and connects to the first semiconductor material BL 101, and a second semiconductor material SL 103 having an internal side surface 1010 that surrounds and connects to the floating body semiconductor material 102. The memory cell structure also includes a first dielectric layer 105a connected to a top surface 1008 of the floating body material 102, a second dielectric layer 105b connected to a bottom surface 1006 of the floating body material 102, a front gate 104a connected to the first dielectric layer 105a, and a back gate 104b connected to the second dielectric layer 105b. In various embodiments, minor modifications are made to the disclosed structures, such as adding a lightly doped drain (LDD), halo implantation, pocket implantation, or channel implantation that are all included within the scope of the invention.
FIG. 1B shows the cell structure shown in FIG. 1A with the front gate 104a and the gate dielectric layer 105a removed. The P- floating body 102 forms a donut shape as shown. Please notice, although this embodiment shows that the shapes for the bit line 101 and floating body 102 are circular, it is obvious that they have any desired shape, such as square, rectangle, triangle, hexagon, etc. These variations shall remain in the scope of the invention.
In one embodiment, the cell structure comprises only one single gate, as shown in FIG. 1B. The floating body 102 is coupled to only one gate 104b as shown. An embodiment of a 3D array structure using this cell structure embodiment is shown in FIG. 1D.
The embodiment shown in FIG. 1A uses an NMOS transistor as the cell. In another embodiment, shown in FIG. 1C, the cell is formed using a PMOS transistor. The bit line 101, floating body 102, and source line 103 are formed by P+, N-, and P+ materials, respectively.
FIG. 1D shows an embodiment of an array structure based on the cell structure shown in FIG. 1A. The array structure comprises vertical bit lines 101a to 101c and floating bodies 102a to 102e. The array structure also comprises source lines 103a to 103e and word lines 104a to 104d. The array structure also includes dielectric layer 105 comprising a gate oxide or high-K material, such as HfOx.
In an embodiment, a three-dimensional (3D) memory array comprises a plurality of memory cells separated by a dielectric layer to form a stack of memory cells. For example, FIG. 1D shows a 3D array having three stacks of memory cells and a particular “memory cell” is identified. Each memory cell in the stack of memory cells comprises a bit line 101 formed from one of a first semiconductor material and a first conductor material, a floating body semiconductor material 102 having an internal side surface that surrounds and connects to the bit line, a source line 103 formed from one of a second semiconductor material and a second conductor material having an internal side surface that surrounds and connects to the floating body semiconductor material 102, and a word line 104 formed from a third conductor material that is coupled to the floating body semiconductor 102 through a dielectric layer 105 to form a gate of the memory cell. Additionally, the bit lines of the stack of memory cells are connected to form a vertical bit line (e.g., 101a).
FIG. 1E shows another embodiment of an array structure according to the invention. This embodiment is similar to the embodiment shown in FIG. 1D except that the cells are single-gate transistors. Also shown in FIG. 1E are insulating layers 106a and 106b that are formed from material, such as oxide.
FIG. 1F shows an equivalent circuit diagram for the array structure shown in FIG. 1D. Referring again to the array structure in FIG. 1D, the word line structures 104a to 104d are connected to word lines WL0 - WL3. The floating bodies structures 102a to 102e are the floating bodies FB0 - FB4. The source line structures 103a to 103e are connected to the source lines SL0 - SL4, and the bit line structure 101a is a vertical bit line (BL). In this embodiment, each floating body (e.g., FB0 - FB4) is coupled to two word lines. This array requires special bias conditions for read and write operations to avoid two cells being selected at the same time. The detailed bias conditions of this embodiment are described with reference to FIG. 3D.
FIG. 1G shows another embodiment of an equivalent circuit diagram of the array structure shown in FIG. 1D. This embodiment is similar to the embodiment shown in FIG. 1F except that the odd word lines, WL1, WL3, and so on, are connected to ground. This turns off the transistors 301c, 301d, 301g, and 301h. In this embodiment, each floating body is coupled to one word line only. However, the storage capacity of this embodiment is reduced to one half when compared with the embodiment shown in FIG. 1F.
FIGS. 1H-I show embodiments of a junction-less transistor cell structure according to the invention.
FIG. 1H shows an N-channel junction-less transistor cell. The bit line 101 and source line 103 comprise N+ semiconductors, such as silicon, and the floating body 102 comprises an N- semiconductor, such as silicon.
FIG. 1I shows a P-channel junction-less transistor cell. The bit line 101 and source line 103 comprise P+ semiconductors, such as silicon, and the floating body 102 comprises a P- semiconductor, such as silicon.
FIGS. 1J-K show embodiments of a tunnel field-effect transistor (T-FET) cell structure according to the invention. For these embodiments, the bit line 101 and the source line 103 comprise semiconductors, such as silicon, that have the opposite type of doping.
FIG. 1J illustrates how the bit line 101 and source line 103 have P+ type of doping and N+ type of doping, respectively.
FIG. 1K illustrates how the bit line 101 and source line 103 have N+ type of doping and P+ type of doping, respectively. The floating body 102 is an intrinsic semiconductor, such as silicon. In another embodiment, the floating body 102 is lightly doped with P-type or N-type impurity. The tunnel FET behaves like a gated diode. It has an advantage of very low off-state leakage current.
FIG. 1L shows another embodiment of the cell structure according to the invention that uses a metal bit line 109 and a metal source line 114. In this embodiment, the drain region 115 and source region 116 of the cell are connected to conductor layers, such as a metal bit line 109 and a metal source line 114, respectively. This reduces the resistance of the bit line and source line. The source region 116 is formed as a donut shape surrounding the floating body 102 as shown.
FIG. 1M shows embodiments of a thin-film structure and an indium-gallium-zinc-oxide (IGZO) transistor cell structure according to the invention. For the thin-film structure, the bit line 109 and the source line 114 comprise conductors, such as metal or polysilicon. The floating body 102 comprises a thin semiconductor layer, such as silicon. The floating body 102 is either an intrinsic semiconductor or doped with P-type or N-type impurity. This structure forms a junction-less thin-film transistor. In another embodiment, the floating body 102 comprises a semiconductor layer with an oxygen tunnel, such as indium-gallium-zinc-oxide (IGZO). Compared with the traditional silicon-based transistor, this embodiment has the advantages of very low off-state leakage current and higher on-cell current.
For all the embodiments for the cell structures shown above in FIGS. 1H-M, the cell may use the double-gate structure shown in FIG. 1A or single-gate structure shown in FIG. 1B. In addition, the cell structure may use a combination of multiple embodiments disclosed herein.
FIG. 2A shows an embodiment of a write data ‘1’ condition of the cell according to the invention. The selected bit line 101 is supplied with a voltage that is high enough to cause impact-ionization to occur. The level of this voltage is dependent on the process technology. In one embodiment, the voltage level is in the range of 1.5 V to 2.5 V. The selected word line 104b is supplied with a voltage level that is lower than the bit line voltage, such as 0.5 V to 1 V. The selected source line (SL) 103a is supplied with 0 V. This condition turns on the cell transistor in saturation mode and causes impact ionization to occur in the bit line junction to generate electron-hole pairs and inject holes into the P- floating body 102a as shown. The holes trapped in the floating body 102a will reduce the threshold voltage (Vt) of the cell transistor to represent the data ‘1’ state.
In one embodiment, the unselected source line 103b is supplied with an inhibit voltage, such as 0.5 V to 1 V. This condition turns off the channel under the gate 104b in the floating body 102b, thus the hole injection may not occur in the floating body 102b.
FIG. 2B shows another embodiment of a write data ‘1’ condition of the cell according to the invention. This embodiment uses a band-to-band tunneling mechanism to write the cell. The selected bit line 101 is supplied with a voltage high enough to cause band-to-band tunneling to occur. The level of this voltage is dependent on the process technology. In one embodiment, the voltage level may be 1.5 V to 2.5 V. The selected word line 104b is supplied with 0 V to turn off the cell transistor and cause band-to-band tunneling to occur in the bit line junction to generate electron-hole pairs and inject holes into the P- floating bodies 102a and 102b as shown. The holes trapped in the floating bodies 102a and 102b will reduce the threshold voltage (Vt) of the cell transistor to represent the data ‘1’ state. It should be noted that in this embodiment, the same data ‘1’ will be written into two floating bodies, such as 102a and 102b that are coupled to the same word line 104b.
FIG. 2C shows an embodiment of a write data ‘0’ condition of the cell according to the invention. FIG. 2D shows an exemplary waveform of the write data ‘0’ condition according to the invention.
At time T0, the selected bit line 101 and selected source line 103a are supplied with a positive voltage. The selected word line 104b is supplied with 0 V. This will turn off the channel of the cell transistors.
At time T1, the selected word line 104b is supplied with a positive voltage. Because the channel is turned off, the word line voltage will couple up the voltage of the floating body 102a, as shown at indicator 117. The word line voltage is selected so that the coupled floating body voltage is higher than the threshold voltage of the P-N junction diode, such as 0.5 V to 0.7 V, to cause forward bias from the floating body 102a to the bit line 101 and source line 103a.
At time T2, the selected bit line 101 and source line 103a are supplied with a low voltage, such as 0 V. This will cause forward bias current to flow from the floating body 102a to the bit line 101 and source line 103a to evacuate the holes stored in the floating body 102a, as shown at indicator 118. This will increase the threshold voltage (Vt) of the cell transistor to represent the data ‘0’ state.
At time T3, the selected bit line 101 and source line 103a are supplied with a positive voltage again to turn off the channel of the cell transistor.
At time T4, the selected word line 104b supplied with 0 V. This will couple low the floating body 102a as shown at indicator 119.
At time T5, the bit line 101 and source line 103a are supplied with 0 V and the write ‘0’ operation is completed.
FIG. 3A shows a threshold voltage (Vt) of the cell data ‘0’ 150 and data ‘1’ 151. During a read operation, the selected word line is supplied with a read voltage (VR) between the Vt of data ‘0’ and ‘1’. This will turn on the data ‘1’ cell and turn off the data ‘0’ cell. A sensing circuit is coupled to the bit line to sense the current to determine the read data.
It should be noted that under the write ‘1’ condition, if more than a desired number of holes are injected into the floating body, it may cause the threshold voltage of the cell transistors to become negative, as shown at indicator 152 in FIG. 3B. These cells may leak current even when they are not selected, and their word lines are supplied with the unselected voltage 0 V. If many unselected cells have negative Vt, the sum of the leakage current may cause read errors.
FIG. 3C shows a special read condition to address the issues illustrated in FIG. 3B. It will be assumed that three word lines, WL0 - WL2 are selected to read.
At time T0, all the bit lines and source lines SL0 - SL2 are pre-charged to a voltage Vpre. The voltage Vpre is lower than the bit line voltage during the write mode to avoid accidentally writing. In one embodiment, Vpre is in the range of 0.5 V to 1 V. All the word lines WL0 - WL2 are supplied with 0 V.
At time T1, the selected word line WL0 is supplied with the read voltage VR, which is between the Vt of the data ‘1’ and ‘0’. The selected source line SL0 is supplied with 0 V. If the selected cell stores data ‘1’, the cell will be turned on and conduct current from the selected bit line to the selected source line to pull low the bit line voltage, as shown at indicator 153. If the selected cell stores data ‘0’, the cell will be turned off, thus the selected bit line will maintain the pre-charged voltage level, as shown at indicator 154. A sense circuit coupled to the selected bit line will sense the current or voltage of the selected bit line to determine the data. Since the unselected bit lines and unselected source lines are pre-charged to the same voltage as the selected bit line, there is no leakage current even if the unselected cells have a negative Vt.
At time T2, the word line WL0 is supplied with 0 V. The source line SL0 is pre-charged to Vpre again. The next selected word line WL1 is supplied with the read voltage VR, and the next selected source line SL1 is supplied with 0 V. This will read the next cell selected by WL1 and SL1.
Similarly, at time T3, the word line WL1 is supplied with 0 V. The source line SL1 is pre-charged to Vpre again. The next selected word line WL2 and source line SL2 are supplied with VR and 0 V, respectively, to read the next selected cell.
FIG. 3D shows a table that summarizes the bias conditions of write data ‘1’, write data ‘0’, and read operations. Vb1 is the bit line voltage during write operation. Vw1 and Vw0 are the word line voltages during write ‘1’ and write ‘0’ operations, respectively. Vpre is the pre-charge voltage during read operation. The term “FL” means the indicated line is floating or floating at an indicated value.
The operation conditions shown in FIG. 3D are for an NMOS embodiment. For a PMOS embodiment, the voltages and polarity are adjusted according to the PMOS transistor’s characteristics. For example, during the read and write operations, the selected word line is supplied with a low voltage, such as 0 V, to turn on the channel. Moreover, during write ‘0’ operation, the bit line 101 is supplied with a positive voltage to cause P-N junction forward bias current to flow from the bit line 101 to the floating body to evacuate the electrons stored in the floating body. These variations and modifications shall be remained within the scope of the invention.
FIGS. 4A-F show simplified process steps for constructing the array structure shown in FIG. 1D.
FIG. 4A shows how multiple sacrificial layers, such as layers 100a to 100d and multiple semiconductor layers, such as silicon or polysilicon layers, forming source lines 103a to 103e, are alternatively deposited to form a stack. The semiconductor source line layers 103a to 103e, have N+ or P+ type of the doping to form NMOS or PMOS transistors, respectively. The sacrificial layers 100a to 100d have different selectivity from the silicon or polysilicon layers for etching solutions. For example, the sacrificial layers 100a to 100d can be oxide or nitride. Then, multiple vertical bit line holes, such as holes for bit lines 101a to 101d are formed by using an anisotropic etching process, such as a deep trench process, to etch through the multiple layers.
FIG. 4B shows how the body of the transistors, such as floating bodies 102a to 102e are formed by using a diffusion process to diffuse the opposite type of impurity of the semiconductor source line layers 103a to 103e through the vertical bit line holes, such as holes 101a to 101d. For example, if the semiconductor source line layers 103a to 103e have N+ type of doping, the body of the transistors, such as floating bodies 102a to 102e are diffused with P-type of doping, such as boron. If the semiconductor source line layers 103a to 103e have P+ type of doping, the body of the transistors, such as floating bodies 102a to 102e are diffused with N- type of doping, such as phosphorus. This forms donut-shape transistor floating bodies 102a to 102e, etc. as shown.
FIG. 4C shows how the vertical bit line holes, such as holes for bit lines 101a to 101d are filled with semiconductor material, such as silicon or polysilicon to form vertical bit lines. The semiconductor layer may have the opposite type of doping as the floating bodies 102a to 102e. For example, if the floating bodies 102a to 102e has P- or N- type of doping, the vertical bit lines 101a to 101d have N+ or P+ type of doping, respectively. Then, vertical slits, such as slits 108a to 108c are formed by using deep trench process to etch through the multiple sacrificial layers 100a to 100d and silicon or polysilicon layers for source lines 103a to 103e. The vertical slits 108a to 108b cut the stack into multiple stacks.
FIG. 4D shows how the sacrificial layers 100a to 100d are selectively removed by using an isotropic etch process, such as wet etch or plasma etch through the slits 108a to 108c.
FIG. 4E shows how a thin-gate dielectric layer 105 is deposited on the surface of the semiconductor source line layers 103a to 103b and the sidewall of the bit lines 101a to 101d through the slits 108a to 108c by using thin-film deposition to form the gate dielectric layer of the transistors. The gate dielectric layer 105 may be oxide or high-K material, such HfOx. After that, a material of the front gate and back gate 104, such as metal or silicon or polysilicon is deposited through the vertical slits 108a to 108c to fill the slits 108a to 108c and the space between the semiconductor source line layers 103a to 103e.
FIG. 4F shows how an anisotropic etch process is performed to vertically etch the gate material in the slits 108a to 108c and form the individual word lines, such as word lines 104a to 104d. As a result, the array structure shown in FIG. 1D is realized. It should be noted that simplified process steps shown in FIGS. 4A-F are used to demonstrate the fundamental process steps according to the invention. Extra steps and minor variations may be applied, and these variations shall remain in the scope of the invention.
FIGS. 4G-H show additional embodiments of array structures according to the invention to form another embodiment of a cell structure shown in FIGS. 5A-B. As illustrated in FIG. 4G, after the process step shown in FIG. 4B are performed, a thin-film deposition or epitaxial thin-film growth process is performed to form a semiconductor layer 133, such as silicon or polysilicon layer, on the sidewall of the vertical holes for the bit lines 101a to 101d. The semiconductor layer 133 is doped with the same type of dopant as the semiconductor source line layers 103a to 103e by using an in-situ doping process or diffusion process through the vertical holes for the bit lines 101a to 101d.
FIG. 4H shows how the vertical holes for the bit lines 101a to 101d are filled with a metal core 134 by using a metal deposition process. This can reduce the resistance of the vertical bit lines to increase the speeds of read and write operations.
FIGS. 4I-J show another embodiment of process steps to form the floating bodies 102a to 102e. After the process steps shown in FIG. 4A are performed, an isotropic etching process, such as wet etch or chemical etch, is performed through the vertical holes for the bit lines 101a to 101d to selectively etch the semiconductor source line layers 103a to 103e to form the recesses as shown.
FIG. 4J shows how the vertical holes for the bit lines 101a to 101e, are filled with a semiconductor material, such as silicon or polysilicon, which is formed by using an epitaxial growth process. In one embodiment, the semiconductor layer in the vertical holes for the bit lines 101a to 101d has the opposite type of impurity of the semiconductor source line layers 103a to 103e. For example, if the semiconductor source line layers 103a to 103e have N+ or P+ type of doping, the semiconductor layer in the vertical holes for the bit lines 101a to 101d have P- or N- type of doping, respectively, which is formed by using an in-situ doping process during the epitaxial growth.
After that, a self-aligned anisotropic etching process, such as dry etch or reactive-ion etch (RIE), is performed using the sacrificial layers 100a to 100d as masks to selectively etch the semiconductor layer in the vertical holes for the bit lines 101a to 101d to form the array structure shown in FIG. 4B. After that, the process steps shown in FIGS. 4C-F are performed to form the array structure shown in FIG. 4F.
FIG. 4K shows an embodiment of the bit line connection of the array structure shown in FIG. 4F. The vertical bit lines, such as 101a to 101d, are connected to horizontal metal bit lines 130a to 130c as shown. Although the embodiment shows the horizontal metal bit lines 130a to 130c located on top of the array, in another embodiment, the metal bit lines 130a to 130c are located in the bottom of the array.
It should be noted that because the vertical bit lines, such as 101c and 101d are connected to the same horizontal metal bit line 130c, the word lines 104a to 104d and word lines 124a to 124d are connected to different decoders’ signals to prevent the cells in vertical bit lines to be selected together. This will require many word line decoders and also increase the process challenge to connect so many word lines to the decoders.
FIG. 4L shows another embodiment of the array structure according to the invention to solve the previously mentioned issue with using many word line decoders. In this embodiment, the vertical bit lines, such as 101a to 101e, are all coupled to the same word line layers 104a to 104d. This reduces the number of the word lines need to be connected to the decoders. Therefore, the number of the word line decoders is reduced. The process step of this embodiment is the same as that of the embodiment shown in FIG. 4F, except that the word line processes are performed through the vertical slits 108a and 108c on two sides of the stack.
FIG. 4M shows the bit line connections of the array embodiment shown in FIG. 4L. FIG. 4M illustrates horizontal metal bit lines 130a to 130c. The vertical bit lines, such as 101a to 101c, are connected to the horizontal metal bit lines 130a to 130c through select transistors 131a to 131c. The select transistors, such as 131a to 131c are formed by using any suitable process and technologies, such as vertical transistors, planar transistors, junction-less transistors, and so on. Although the embodiment shows NMOS transistors as an example, the select transistors, such as 131a to 131c, can be formed as PMOS transistors as well. Moreover, although the embodiment shows that the horizontal metal bit lines 130a to 130c and the select transistors, such as 131a to 131c, are located on top of the array, in another embodiment, the bit lines and the select transistors can be located in the bottom of the array as well.
The gates 132a to 132c of the select transistors are connected to different decoders’ signals. For example, when the gate 132a is selected, it will turn on the select transistors 131a to 131c to couple the vertical bit lines 101a to 101c to the horizontal metal bit lines 131a to 131c, respectively. The unselected gates 132b and 132c will turn off the associated select transistors. This presents multiple vertical bit lines to be coupled to the same metal bit line.
FIG. 4N shows another embodiment of an array architecture according to the invention. This embodiment is similar to the embodiment shown in FIG. 1D except that the gate dielectric layer 105 is replaced by a charge-trapping layer 160, which traps electric charge such as electrons. When electrons are trapped inside the charge-trapping layer, the threshold voltage of the transistor is increased. This results in lower cell current during read operations. Therefore, the data can be stored in the charge-trapping layer 160 in terms of the number of trapped electrons. Because the trapped electrons remain in the charge-trapping layer after power down, this embodiment can be used as a non-volatile memory, such as 3D NOR flash memory.
In one embodiment, the charge trapping layer 160 is formed as a nitride layer or oxide-nitride layers. Because a nitride layer’s electrical barrier is lower than an oxide layer’s, this embodiment allows the data to be written in lower gate voltage and shorter time. However, because of the lower electrical barrier, it is easier for the electrons to escape from the charge-trapping layer 160, thus the data retention time is also shorter.
This embodiment is suitable for the application of non-volatile buffer memory. In normal operation, the data is stored in the floating bodies 102a to 102e of the cells, as described in the previous embodiments shown in FIG. 2A to FIG. 3B. When the system becomes idle or during an accidental power loss event, the data stored in the floating bodies 102a to 102e can be quickly written to the charge-trapping layer 160 to preserve the data. Because the electrons stored in the charge-trapping layer 160 may escape after a period of time, a refresh operation with longer duration may still be needed during the system idle. However, since the frequency of the refresh operation is reduced, the power consumption is also reduced. In the case of power loss, a battery or a large capacitor may be utilized to temporarily maintain the power of the system until the data stored in the charge-trapping layer 160 is copied to another non-volatile memory, such as NAND flash memory or hard disk drives.
In another embodiment, the charge-trapping layer 160 comprises a sandwich of oxide-nitride-oxide (ONO) layers. Due to the oxide layer having a higher electrical barrier than the nitride layer, the electrons trapped in the nitride layer are more difficult to escape. Therefore, the data retention time for this embodiment is much longer, like years. This embodiment may be used as a permanent non-volatile memory. However, due to the oxide layer’s higher electrical barrier, this embodiment requires higher write voltage, such as 10 V to 20 V.
FIG. 4O shows an embodiment of a non-volatile program operation to write the data stored in the floating bodies 102a and 102b to the charge-trapping layer 160. Assuming the data stored in the floating bodies 102a and 102b is ‘1’ and ‘0’, respectively. During the non-volatile program operation, the front gate 104b is supplied with a program voltage, such as 3-5 V for a nitride layer and 10-20 V for ONO layers. The bit line 101 and the source lines 103a and 103b are floating. For the floating body 102a, the holes stored in the floating body 102a reduce the electrical field between the front gate 104b and the floating body 102a to below the threshold of the Fowler-Nordheim (F-N) tunneling mechanism. Therefore, F-N tunneling may not happen. For the floating body 102b, due to the fact there are no holes, the electrical field between the front gate 104b and the floating body 102b is sufficient to induce F-N tunneling, and thus electrons may be injected into the charge-trapping layer 160 and trapped inside the layer to increase the threshold voltage of the cell transistor.
FIG. 4P shows another embodiment of a 3D floating body cell array structure according to the invention. This embodiment is similar to the one shown in FIG. 1D except that the insulating layers 161a and 161b, such as oxide or nitride, are formed in the junctions of the vertical bit lines 101a and 101b and the odd word line layers 104b and 104d. This prevents the channels induced by the even word lines 104b and 104d to reach the vertical bit lines 101a and 101b. In this embodiment, the even word lines 104a and 104c are connected to normal word line (WL) signals, and the odd word lines 104b and 104d are connected to ‘erase word lines (EL)’ signals. The erase word line 104b is activated during write ‘0’ operation to ‘erase’ the data stored in the cells. The array structure allows the cells to perform special write ‘0’ operation shown in FIGS. 4Q-R. For a detailed description of the array structure, please refer to FIG. 1D.
FIG. 4Q shows a write ‘0’ condition of the array structure embodiment shown in FIG. 4P. FIG. 4Q shows the vertical bit line (BL) 101 and floating bodies (FB) 102a and 102b. Also shown are source lines (SL) 103a and 103b, word lines (WL) 104a and 104c, erase word line (EL) 104b, gate dielectric layer 105 and insulating layer 161.
FIG. 4R shows an embodiment of write ‘0’ waveforms. At time T0, the bit line (BL), source line (SL), and erase line (SL) are supplied with a positive voltage. This will couple up the voltage of the floating bodies 102a and 102b as shown at indicator 117. The applied voltage is high enough to couple the floating bodies to a voltage higher than the threshold voltage of the P/N junction, such as 0.5 V to 0.7 V.
At time T1, the bit line (BL) is supplied with 0 V. This will cause forward bias current to flow from the floating bodies 102a and 102b to the bit line 101, and evacuate the holes stored in the floating bodies 102a and 102b to lower their potential, as shown at indicator 118. Due to the insulating layer 161, the channel induced by the erase word line 104b will not reach the bit line 101. This prevents the channel voltage from being discharged by the bit line voltage to reduce the voltage coupling of the floating bodies. The word lines 104a and 104c are supplied with 0 V to turn off the channels induced by the word lines to prevent leakage current from the source lines to the bit line.
At time T2, the erase word line 104b and source lines 103a and 103b are supplied with 0 V. This will couple down the floating bodies 102a and 102b, as shown at indicator 119, to be lower than its initial voltage. Thus, the threshold voltage of the floating body cells are increased, which represents the state of data ‘0’.
FIG. 4S shows bias conditions of write data ‘1’, write data ‘0’, and read operations for the array embodiment shown in FIG. 4P. The conditions are similar to the ones shown in FIG. 3D except for the write ‘0’ condition. During the write ‘0’ condition, the selected erase word line (EL) and source line (SL) are supplied with a positive voltage Vw0, which shall be high enough to couple up the floating body of the cell to be higher than the threshold voltage of the P/N junction. During read and write ‘1’ operations, the erase word line (EL) is supplied with 0 V or any other suitable voltage. Because the channel induced by the erase word line (EL) does not reach the bit line, it will not cause current leakage even when the channel is turned on.
FIGS. 4T-Z show an embodiment of process steps to form the cell array structure shown in FIG. 4P.
FIG. 4T shows how multiple semiconductor source line layers 103a to 103c, such as silicon, and insulating layers 162a and 162b, are alternately deposited to form a stack. The even insulating layers, such as 162a, and odd insulting layers, such as 162b, are different material. For example, in one embodiment, the even insulating layer 162a comprises an oxide layer and the odd insulating layer 162b comprises a nitride layer.
FIG. 4U shows how multiple vertical holes, such as hole 101, is formed by using an anisotropic etching process, such as deep trench or dry etch to etch through the multiple semiconductor source line layers 103a to 103c and the insulating layers 162a and 162b to form the vertical bit line pattern. After that, recessed area for the insulating layer 161 is formed in the odd insulting layers, such as layer 162b by using an isotropic etching process, such as wet etch or chemical etch through the hole for the bit line 101.
FIG. 4V shows how the hole for the bit line 101 is filled with an insulating layer which is different from the insulating layer 162b. For example, if the insulting layer 162b is nitride, the insulator used in filling the hole for the bit line 101 may be oxide. After that, the insulator in the hole for the bit line 101 is etched using an anisotropic etching process, such as dry etch, to remove the insulator in the hole for the bit line 101 except for the residual in the recessed area for the insulating layer 161.
FIG. 4W shows how the floating bodies 102a to 102c are formed by using a diffusion process to diffuse the semiconductor source line layers 103a to 103c with the opposite type of impurity through the hole for the bit line 101. For example, if the semiconductor source line layers 103a to 103c have N+ type or P+ type of doping, the floating bodies 102a to 102c have P- type or N- type of doping, respectively. This step forms ‘donut’ shapes for the floating bodies 102a to 102c.
FIG. 4X shows how the hole for the bit line 101 is filled with semiconductor to form a vertical bit line. The semiconductor may be doped with the opposite type of impurity of the floating bodies 102a to 102c by using an in-situ doping process.
FIG. 4Y shows how even insulting layers, such as 162a, are selectively etched by using an isotropic etching process, such as wet etch or chemical etch. After that, the odd insulating layers, such as 162b, are selectively etched by using an isotropic etching process, such as wet etch or chemical etch. Because the insulating layers 161 and 162b are different materials, the insulating layer 161 will not be etched.
FIG. 4Z shows how a gate dielectric layer 105 is formed on the surface of the array structure by using a thin-film deposition process. After that, the spaces previously occupied by the insulating layers 162a and 162b, as shown in FIG. 4Y, are filled with a control gate material, such as metal or polysilicon, to form the word line 104a and erase word line 104b.
FIG. 5A shows another embodiment of a cell structure according to the invention. This embodiment is similar to the one shown in FIG. 1A except that a metal core is formed in the center of the bit line 101 to form a metal bit line 109 to reduce the bit line resistance.
FIG. 5B shows the cell structure of FIG. 5A with the front gate 104a and gate dielectric layer 105a removed to show the inner structure. The cell structure shown in FIGS. 5A-B is formed by using a similar process to that shown in FIGS. 4A-D except that in FIG. 4D, the silicon or polysilicon layer for bit line 101a is deposited on the surface of the sidewall of the vertical bit line hole instead of filling the bit line hole. Then, the bit line hole is filled with metal to form a metal bit line 109.
FIG. 5C shows another embodiment of a cell structure according to the invention. FIG. 5D shows the cell structure of FIG. 5C with the front gate 104a and the gate dielectric layer 105a removed.
The embodiment shown in FIG. 5C is similar to the embodiment shown in FIG. 5A except that an N+ silicon or polysilicon 120 is formed as a donut shape island for each cell and connected to the metal bit line 109 that is formed by filling the vertical bit line hole with metal. For comparison, the N+ silicon or polysilicon layer for bit line 101 shown in FIG. 5A is a continuous layer formed on the sidewall of the metal bit line 109. Similarly, the cell structure shown in FIGS. 5C-D is formed by a similar process to that shown in FIGS. 4A-D except that in FIG. 4B, after the P- floating body 102 is formed, the N+ region 120 is formed by using an implantation or diffusion through the bit line hole. Then, the bit line hole is filled with the metal to form the metal bit line 109.
FIG. 6A shows another embodiment of a cell structure according to the invention. FIG. 6B shows the cell structure shown in FIG. 6A with the front gate 104a and gate dielectric layer 105a removed. This embodiment is similar to the embodiment shown in FIG. 1A except that the cell is divided into two cells by an insulating layer 110, such as an oxide. The insulating layer 110 divides the floating body into 102a and 102b, and divides the front gate into 104a and 104c, and divides the back gate into 104b and 104d. In this way, the bit line 101 is connected to two cells, thus the memory array capacity is doubled. Similar to the embodiment shown in FIG. 1A, this cell structure may be formed by using NMOS or PMOS transistors. Besides, the floating bodies 102a and 102b and bit line 101 may be any shape, such as circular.
FIGS. 6C-D show another embodiment of a cell structure according to the invention. This embodiment is similar to the embodiment shown in FIGS. 6A-B except that the floating bodies 102a and 102b and bit line 101 are circular.
FIG. 7 shows an embodiment of an array structure based on the cell structure shown in FIG. 6A. The array structure of FIG. 7 includes bit lines 101a to 101c, floating bodies 102a to 102e, source lines 103a and 103b, word lines 104a and 104b, gate dielectric layer 105, and insulating layers 110a and 110b that comprise an oxide.
FIGS. 8A-F show simplified process steps for forming the array structure shown in FIG. 7.
FIG. 8A shows how multiple sacrificial layers, such as layers 100a and 100b, and multiple N+ silicon or polysilicon layers, such as layers for bit lines 101a and 101b, are alternatively deposited to form a stack. Then, multiple vertical slits, such as slits 121a and 121b are formed by using a deep trench process to etch through the multiple layers.
FIG. 8B shows how a P- floating body, such as P- floating bodies 102a to 102e are formed by using implantation or diffusion through the slits, such as slits 121a and 121b. This process forms P- silicon or polysilicon strips.
FIG. 8C shows how the slits, such as slits 121a and 121b are filled with N+ silicon or polysilicon. Then, vertical slits, such as vertical slits 108a to 108c are formed by a deep trench process to etch through the stack.
FIG. 8D shows how the sacrificial layers, such as layers 100a and 100b are removed by using an isotropic etch process, such as wet etch or plasma etch, through the slits 108a to 108c.
FIG. 8E shows how a thin dielectric layer 105 is deposited on the surface of the sidewall through the slits 108a to 108c. Then, the material for the front gate and back gate, such as metal or silicon or polysilicon is deposited to fill the slits 108a to 108c and the space between the silicon or polysilicon layers for source lines 103a and 103b, etc.
FIG. 8F shows how vertical bit lines, such as bit lines 101a and 101b are formed by using a deep trench process to etch holes for the bit lines 110a and 110b, etc. and filling the holes with an insulator, such as an oxide. After that, an anisotropic etch process is performed to vertically etch the gate material in the slits 108a to 108c to form the individual word lines, such as word lines 104a and 104b, etc. As a result, the array structure shown in FIG. 7 is realized.
FIG. 9A shows another embodiment of a cell structure according to the invention. The cell structure in FIG. 9A comprises N+ silicon or polysilicon that forms a bit line 101, a P-floating body 102 for charge storage, N+ silicon or polysilicon that forms a source line 103, a front gate 104, and a gate dielectric layer 105. The back gate is not shown to make it easier to illustrate. The front gate 104 of the cells on multiple layers are connected to form a word line (WL). In this embodiment, because the word line 104 runs in a vertical direction, the horizontal N+ silicon or polysilicon line becomes the bit line 101, and the vertical N+ silicon or polysilicon line becomes the source line 103.
It should be noted that when talking about single cell (transistor) structure, the front gate structure is referred to as a gate. If the cell has dual gates, one gate is called the “front gate” and the other gate is called the “back gate.” In an array level structure, the gates of multiple cells are connected to form a word line, so the gate structures are also referred to as word lines.
FIG. 9B shows an embodiment of an array structure based on the cell structure shown in FIG. 9A. The structure of FIG. 9B comprises bit lines 101a and 101b, floating bodies 102a to 102e, source lines 103a and 103b, word lines 104a and 104b, gate dielectric layers 105a and 105b, and insulating layers 113a and 113b, such as oxide layers.
FIGS. 10A-D show simplified process steps for constructing the cell structure shown in FIG. 9A.
FIG. 10A shows how multiple N+ silicon or polysilicon layers, such as layers for bit lines 101a and 101b, and multiple insulating layers, such as layers 111a and 111b are alternatively deposited to form a stack. Then, multiple vertical slits, such as slits 121a and 121b are formed by using a deep trench process to etch through the multiple layers.
FIG. 10B shows how P-bodies, such as P- floating bodies 102a to 102e are formed by using implantation or diffusion through the slits 121a and 121b. This forms P- silicon or polysilicon strips.
FIG. 10C shows how the slits 121a and 121b are filled with N+ silicon or polysilicon.
FIG. 10D shows how multiple holes are formed by a deep trench process and thin gate dielectric layers, such as layers 105a and 105b, are formed on the sidewall of the holes. Then, the holes are filled with the gate material, such as metal or silicon or polysilicon to form vertical word lines, such as word lines 104a and 104b. As a result, the array structure shown in FIG. 9B is realized.
FIG. 11A shows another embodiment of a cell structure according to the invention. The cell structure shown in FIG. 11A comprises a bit line 101 formed from N+ silicon or polysilicon, a P- floating body 102 for charge storage, a source line 103 formed from N+ silicon or polysilicon, a front gate 104, and a gate dielectric layer 105. The back gate is not shown to make it easier to illustrate. The front gate 104 of the cells on multiple layers are connected to form a word line (WL). In this embodiment, because the word line 104 runs in a vertical direction, the horizontal N+ silicon or polysilicon line becomes the bit line 101. The vertical N+ silicon or polysilicon line becomes the source line 103.
FIG. 11B shows an embodiment of an array structure based on the cell structure shown in FIG. 11A. The array structure shown in FIG. 11B comprises bit lines 101a to 101b, floating bodies 102a to 102e, source lines 103a and 103b, word lines 104a and 104b, gate dielectric layers 105a and 105b, and insulating layers 111a and 111b that are formed from a material such as an oxide.
FIGS. 12A-D shows simplified process steps for constructing the cell structure shown in FIG. 11A.
FIG. 12A shows how multiple N+ silicon or polysilicon layers, such as layers for bit lines 101a and 101b, and multiple insulating layers, such as layers 111a and 111b are alternatively deposited to form a stack. Then, multiple vertical slits, such as vertical slits 108a to 108c are formed by using a deep trench process to etch through the multiple layers.
FIG. 12B shows how P- floating bodies, such as P- floating bodies 102a to 102e are formed by using implantation or diffusion through the vertical slits 108a to 108c. This forms P- silicon or polysilicon strips.
FIG. 12C shows how the slits 108a to 108c are filled with N+ silicon or polysilicon to form the source lines 103a to 103c.
FIG. 12D shows how multiple holes are formed by a deep trench process and thin gate dielectric layers 105a and 105b are formed on the sidewall of the holes. Then, the holes are filled with the gate material, such as metal or silicon or polysilicon, to form vertical word lines, such as word lines 104a and 104b. As a result, the array structure shown in FIG. 11B is realized.
FIG. 13A shows another embodiment of a DRAM-replacement technology according to the invention. This technology uses a 3D thyristor cell and includes P+ silicon or polysilicon for bit line 101, N- silicon or polysilicon 112, P- silicon or polysilicon 102, and N+ silicon or polysilicon for source line 103. The P+ silicon for bit line 101, P- silicon 112, and P-silicon 102 form a PNP bipolar transistor. The N- silicon 112, P- silicon 102, and N+ silicon for source line 103 form an NPN bipolar transistor. The P+ silicon or polysilicon for bit line 101 and N+ silicon or polysilicon for source line 103 are connected to a bit line (BL) and a source line (SL), respectively. Also included are a front gate (FG) 104a and back gate (BG) 104b, respectively, and gate dielectric layers 105a and 105b. The two bipolar transistors form a gate-assisted thyristor cell, as shown in the circuit diagram of FIG. 14A.
FIG. 13B shows the cell structure of FIG. 13A with the front gate 104a and the gate dielectric layer 105a removed. The P- floating body 102 comprises a donut shape as shown.
FIG. 13C shows another embodiment of a 3D thyristor cell structure according to the invention. This embodiment is similar to the embodiment shown in FIG. 13A except that the front gate 104a and back gate 104b are replaced by insulating layers 113a and 113b. This forms a non-gate-assisted thyristor cell as shown in the circuit diagram shown in FIG. 14B.
It should be noted that although the embodiments shown in FIGS. 13A-C show that the shape for the bit line 101 and body 102 is circular, it is obvious that they may have any other shapes, such as square, rectangle, triangle, hexagon, etc. Also, in another embodiment, the materials of 101, 112, 102, and 103 can be reversed to be N+, P-, N-, and P+, respectively. Moreover, similar to FIGS. 5A-D, the cell may have a metal core in the center of bit line 101 to reduce bit line resistance. These variations shall remain in the scope of the invention.
FIG. 14C shows a current to voltage (I-V) curve of the thyristor cell shown in FIG. 13A. When a voltage difference from the BL to WL exceeds a ‘trigger voltage’ 1401, the two bipolar transistors are turned on and cause latch-up to occur. This causes the thyristor cell to conduct current from the BL to the WL, thus it becomes an ‘on-cell’. When the voltage difference from the BL to WL is lowered or reversed to reduce the current to below a ‘holding current’ 1402, the transistors are turned off, thus the cell becomes an ‘off-cell’. By using this process, the thyristor cell functions as a memory cell to store data. Because the cell can be switched between on-cell and off-cell in very short time, such as in the nanosecond range, the cell may be used for high-speed memory, such as for replacement of DRAM or SRAM.
FIG. 15A shows an embodiment of a 3D array structure based on the cell structure shown in FIG. 13A. The 3D array structure shown in FIG. 15A includes P+ silicon or polysilicon bit lines 101a to 101c, N- silicon or polysilicon 112a to 112e, P- silicon or polysilicon 102a to 102e, and N+ silicon or polysilicon word lines 103a and 103b. Also included are front 104a and back 104b gates, and gate dielectric layer 105.
FIG. 15B shows an embodiment of a 3D array structure based on the cell structure shown in FIG. 13C. This embodiment is similar to the embodiment shown in FIG. 15A except that the word line layers 104a and 104b, etc. are replaced with insulating layers 113a and 113b, etc. The 3D array structures shown in FIGS. 15A-B are formed by using similar process steps as shown in FIGS. 4A-F.
FIG. 16A shows another embodiment of a thyristor cell structure according to the invention. FIG. 16B shows the cell structure shown in FIG. 16A with the front gate 104a and gate dielectric layer 105a removed.
The embodiment shown in FIG. 16A is similar to the embodiment shown in FIG. 13A except that the cell is divided into two cells by an insulating layer 110, such as an oxide material. In this configuration, the memory array capacity is doubled. Similar to FIG. 6C and FIG. 6D, the shapes of the material 101, 112, and 102 can be circular or any other suitable shapes.
FIG. 16C shows another embodiment of a thyristor cell structure according to the invention. This embodiment is similar to the embodiment shown in FIG. 16A except that the front gate 104a and back gate 104b are replaced by insulating layers 113a and 113b. This forms a non-gate-assisted thyristor cell as shown in FIG. 14B.
FIG. 17A shows an embodiment of a 3D array structure based on the cell structure shown in FIG. 16A. The embodiment shown in FIG. 17A comprises P+ silicon or polysilicon bit lines 101a to 101c, etc., N- silicon or polysilicon 112a to 112e, etc., P- silicon or polysilicon floating bodies 102a to 102e, etc. N+ silicon or polysilicon source lines 103a and 103b, etc. Also included are front 104a and back 104b gates, gate dielectric layer 105, and insulating layers 110a and 110b.
FIG. 17B shows an embodiment of a 3D array structure based on the cell structure shown in FIG. 16C. This embodiment is similar to the embodiment shown in FIG. 17A except that the word line layers 104a and 104b, etc. are replaced with insulating layers 113a and 113b, etc. The 3D array structures shown in FIG. 17A and FIG. 17B are formed by using similar process steps to those shown and described with reference to FIGS. 8A-F.
FIG. 18A shows another embodiment of a thyristor cell structure according to the invention. The cell structure shown in FIG. 18A comprises P+ silicon or polysilicon for bit line 101, N- silicon or polysilicon 112, P- silicon or polysilicon 102, and N+ silicon or polysilicon for source line 103. The materials 101 and 103 are connected to a bit line and a source line, respectively. Also shown is a front gate 104 and a gate dielectric layer 105. A back gate is not shown to make it easier to illustrate. In this embodiment, the front gate 104 runs in vertical direction.
FIG. 18B shows an embodiment of a 3D array structure based on the cell structure shown in FIG. 16C. The array structure shown in FIG. 18A comprises P+ silicon or polysilicon bit lines 101a and 101b, etc., N- silicon or polysilicon 112a to 112e, etc., P- silicon or polysilicon 102a to 102e, etc. N+ silicon or polysilicon source lines 103a and 103b, etc., front gate 104a and back gate 104b, gate dielectric layers 105a and 105b, etc., and insulating layers 113a and 113b. This embodiment is formed by using similar process steps as shown and described with respect to FIGS. 10A-D.
FIG. 19A shows another embodiment of a 3D array structure according to the invention that uses ‘tunnel field-effect transistor (TFET)’ technology. FIG. 19A comprises vertical bit lines 101a and 101b, floating bodies 102a to 102e, and source lines 103a to 103e. In an embodiment, the floating bodies 102a to 102e are formed from an intrinsic semiconductor material, such as silicon.
In an embodiment, the vertical bit lines 101a and 101b and source lines 103a to 103e are formed from P-type or N-type of heavily doped semiconductor material, such as silicon. The vertical bit lines 101a to 101b and the source lines 103a to 103e are material having the opposite type of doping.
In one embodiment, word lines 104a to 104d are formed from conductor material, such as metal or polysilicon. A gate dielectric layer 105 is formed from material, such as gate oxide or high-K material, such as HfO2. Also shown are insulating layers 161a to 161d that are formed from material, such as an oxide or a nitride.
FIG. 19B shows a cross-section of the array structure shown in FIG. 19A that is taken at cross-section indicator A-A’ to reveal the structure of the insulating layer 161a. The structure of the insulating layers 161a to 161d are formed by using an isotropic etching process, such as wet etch, to selectively form recesses through vertical bit line holes, and then forming the insulating layer inside the recesses, as in the process step shown in FIG. 4B.
In another embodiment, a conductor core 163, such as metal or polysilicon, is formed in the center of the vertical bit lines 101a and 101b to reduce the resistance of the vertical bit lines, as shown in FIG. 19B. The conductor core 163 is formed by using a thin-film deposition or a thin-film epitaxial growth process to form a layer of semiconductor for bit line 101a, such as silicon on the sidewall of the vertical hole, and then filling the center of the hole with the conductor core 163.
FIG. 20A shows a detailed front view of the 3D array structure shown in FIG. 19A. This view includes vertical bit line 101a, floating bodies 102a, 102aʹ, 102b, and 102bʹ, source lines 103a and 103b, word lines 104a to 104c, gate dielectric layer 105, and insulating layers 161a to 161c. It should be noted that the word lines 104a to 104c only partially cover the floating bodies, such as floating bodies 102a and 102b. An electric charge, such as electron holes, can be stored in the portion of the floating bodies 102a and 102b under the word lines 104a to 104c. The number of the stored electron holes can alter the threshold voltage of the cell transistors to represent the data 1 or 0. The portion of the floating bodies 102aʹ and 102bʹ not being covered by the word lines 104a to 104c form potential wells to isolate the stored electron holes from the bit line 101a.
It should be noticed that the above cell can be operated using dual-gate bias conditions. The even word lines, such as 104a and 104c, are supplied with the front-gate bias condition, and the odd word lines, such as 104b, are supplied with the back-gate bias condition.
In one embodiment, the bit line 101a and the source lines 103a and 103b have N-type and P-type of doping, respectively. During read operations, the bit line 101a is supplied with a positive voltage and the source lines 103a and 103b are supplied with a low voltage, such as 0 V. This causes the cells to operate in a reverse bias condition between source and drain.
In another embodiment, the bit line 101a and the source lines 103a and 103b have N-type and P-type of doping, respectively. During read and write operations, the bit line 101a are supplied with low voltage, such as 0 V, and the source lines 103a and 103b are supplied with a positive voltage. This causes the cells to operate in a forward bias condition between the source and drain. The word lines 104a and 104b provide controllable injection barriers.
In another embodiment, the bit line 101a and the source lines 103a and 103b have P-type and N-type of doping, respectively. During read operations, the bit line 101a is supplied with a positive voltage and the source lines 103a and 103b are supplied with a low voltage, such as 0 V. This causes the cells to operate in a forward bias condition between the source and drain. The word lines 104a and 104b provide controllable injection barriers.
FIG. 20B shows another embodiment of the detailed front view of the 3D array structure according to the invention. This embodiment is similar to the one shown in FIG. 20A except that the word line 104b is replaced with an insulating layer 161b. This forms a single-gate cell structure.
FIG. 20C shows another embodiment of the vertical cross section view of the 3D array structure according to the invention. This embodiment is similar to the one shown in FIG. 20A except that the insulating layer 161b shown in FIG. 20A is removed and the odd word lines, such as 104b cover the entire floating bodies 102a and 102aʹ.
FIG. 21A shows another embodiment of the 3D array structure according to the invention. This embodiment includes vertical word lines 171a and 171b formed of conductor material, such as metal or polysilicon. This embodiment also includes gate dielectric layer 178 made from material, such as gate oxide or high-K material, such as HfO2.
Also shown in FIG. 21A are floating bodies 172a to 172d that are formed by using an isotropic etching process, such as wet etch to selectively form recesses in the insulating layers 176a to 176d through vertical bit line holes, and then forming the silicon layer inside the recesses, as in the process step shown in FIG. 4B.
Also shown in FIG. 21A are bit line layers 173a to 173b and source line layers 174a and 174b. The bit line layers 173a and 173b and the source lines layers 174a and 174b are formed of heavily doped semiconductor, such as silicon. The bit line layers 173a and 173b and the source line layers 174a and 174b have the same type of doping. The floating bodies 172a to 172d are formed of lightly doped semiconductor layers, such as silicon with the opposite type of doping as the bit lines 173a and 173b and the source lines 174a and 174b.
During read operations, the vertical word line 171a is supplied with a read voltage to turn on the vertical channels, such as channels 175a and 175b between the bit lines 173b and the source line 174b to conduct current. Electric charge, such as electron holes, are be stored in the floating bodies 172a to 172d to alter the threshold voltage of the cell transistor to represent data 1 or 0.
FIG. 21B shows another embodiment of the 3D array structure according to the invention. This embodiment is similar to the one shown in FIG. 21A except that the insulating layers 176a to 176d are replaced with conductor layers 177a to 177d, comprising material, such as metal or polysilicon. Also shown is a gate dielectric layer 179 comprising material, such as gate oxide or high-K material, such as HfO2. This forms a dual-gate cell structure which include front gates 171a and 171b and back gates 177a to 177b. During read and write operations, the front gates and back gates are supplied with different bias conditions.
FIG. 21C shows another embodiment of a 3D array structure according to the invention. This embodiment is similar to the embodiment shown in FIG. 21A except that only the even layers of floating bodies 172a and 172c are formed. The odd layers of floating bodies 172b and 172d shown in FIG. 21A are eliminated. For comparison, the structure shown in FIG. 21A shares the bit lines and source lines with adjacent cells. The structure shown in FIG. 21C dedicates one bit line and one source line for each cell.
FIG. 21D shows another embodiment of a 3D array structure according to the invention. This embodiment is similar to the embodiment shown in FIG. 21B except that only the even layers of floating bodies 172a and 172c are formed. The odd layers of floating bodies 172b and 172d shown in FIG. 21A are eliminated. For comparison, the structure shown in FIG. 21B shares the bit lines and source lines with adjacent cells. The structure shown in FIG. 21D dedicates one bit line and one source line for each cell.
FIG. 22A shows another embodiment of a 3D cell structure according to the invention. FIG. 22B shows the cell shown in FIG. 22A separated into three portions (or sections) to show the cell’s inner structure. In one embodiment, multiple layers of the cell structure shown in FIG. 22A are stacked to form a high-density cell array.
The materials 181 and 183 are heavily doped semiconductor layers, such as P+ or N+ silicon. The material 181 forms a vertical bit line. The material 183 forms a horizontal source line. The material 182 is a lightly doped semiconductor, such as P- or N- silicon material. The semiconductor layer 182 has the opposite type of doping of the materials 181 and 183. As shown in FIG. 22B, the material 182 forms the floating body of the cell. This forms a floating-body memory cell.
In another embodiment, the material 182 comprises an intrinsic semiconductor, such as silicon. The materials 181 and 183 are heavily doped semiconductor material, such as P+ or N+ silicon material. The materials 181 and 183 have the opposite type of doping. This forms a tunnel field effect transistor (TFET) type of memory cell.
The cell comprises two gates 184 and 186. The gate 184 is connected to a word line. The gate 186 is connected to a read voltage. Gate dielectric layers 185a and 185b comprise gate oxide or high-K material, such as HfO2. Also shown are channel regions 188a and 188b. In one embodiment, the channel length of the gate 186 is longer than that of the gate 184. This reduces the coupling effect of the word line.
Also shown is an insulating layer 187 comprising an oxide to prevent the short of the materials 181 and 183. In one embodiment, a conductor core 189 comprising material, such as a metal, is formed in the center of the vertical bit line 181 to reduce the bit line resistance. The conductor layer 189 can be eliminated without affecting the function of the cell.
FIG. 23A shows another embodiment of a 3D cell structure according to the invention. FIG. 23B shows the cell shown in FIG. 23A separated into four portions (or sections) to show the cell’s inner structure. Multiple layers of the cell structure shown in FIG. 23A are stacked to form a high-density cell array.
The embodiment shown in FIG. 23A is similar to the embodiment shown in FIG. 22A except that an additional layer 180 is added. The layers 180, 181 and 183 are heavily doped semiconductor layers comprising material, such as P+ or N+ silicon. Layer 181 forms a vertical bit line. Layer 183 forms a horizontal source line. The layers 180 and 181 have the same type of doping so that layer 180 becomes an extension of the vertical bit line 181.
The layer 182 is a lightly doped semiconductor, such as P- or N- silicon. The semiconductor layer 182 has the opposite type of doping of the layers 181 and 183. As shown in FIG. 23B, the material 182 forms the floating body of the cell. This results in a floating-body memory cell.
In another embodiment, the material 182 is an intrinsic semiconductor, such as silicon. The material 181 and 183 are heavily doped semiconductors, such as P+ or N+ silicon. The material 181 and 183 have the opposite type of doping. This forms a tunnel field effect transistor (TFET) type of memory cell.
The cell comprises two gates 184 and 186. The gate 184 is connected to a word line. The gate 186 is connected to a read voltage. Gate dielectric layers 185a and 185b comprise material, such as gate oxide or high-K material, such as HfO2. Also shown are channel regions 188a and 188b. In one embodiment, the channel length of the gate 186 is longer than that of the gate 184. This reduces the coupling effect of the word line.
Also shown in an insulating layer 187 comprising material, such as oxide to prevent the short of layers 181 and 183. In one embodiment, a conductor core 189 comprising material, such as metal, is formed in the center of the vertical bit line 181 to reduce the bit line resistance. In one embodiment, the conductor layer 189 can be eliminated without affecting the function of the cell.
FIG. 24A shows another embodiment of the 3D cell structure according to the invention. FIG. 24B shows the di-section view of the structure shown in FIG. 24A. Multiple layers of the cell structure shown in FIG. 24A are stacked to form a high-density cell array.
The embodiment shown in FIG. 24A is similar to the embodiment shown in FIG. 23A except that the second gate 186 is removed. The materials 180, 181 and 183 are heavily doped semiconductor layers, such as P+ or N+ silicon. The material 181 forms a vertical bit line. The material 183 forms a horizontal source line. The material 180 and 181 have the same type of doping so that the material 180 becomes an extension of the vertical bit line 181.
The material 182 is a lightly doped semiconductor, such as P- or N- silicon. The semiconductor layer 182 has the opposite type of doping of materials 181 and 183. As shown in FIG. 24B, the material 182 forms a floating body of the cell. This results in a floating-body memory cell.
In another embodiment, the material 182 comprises an intrinsic semiconductor, such as silicon. The material 181 and 183 are heavily doped semiconductors, such as P+ or N+ silicon. The materials 181 and 183 have the opposite type of doping. This forms a tunnel field effect transistor (TFET) type of memory cell.
The cell comprises only one gate 184. The gate 184 is connected to a word line. A gate dielectric layer 185 comprises material, such as gate oxide or high-K material, such as HfO2. Also shown are channel regions 188a and 188b.
An insulating layer 187 comprises material, such as oxide to prevent the short of the materials 181 and 183. In one embodiment, a conductor core 189 comprising material, such as metal, is formed in the center of the vertical bit line 181 to reduce the bit line resistance. In one embodiment, the conductor layer 189 is eliminated without affecting the function of the cell.
FIG. 25A shows another embodiment of 3D cell structure according to the invention. FIG. 25B shows a di-section view of the structure shown in FIG. 25A. Multiple layers of the cell structure shown in FIG. 25A are stacked to form a high-density cell array.
This embodiment is similar to the embodiment shown in FIG. 24A except that the semiconductor layer extension 180 is removed. The materials 181 and 183 are heavily doped semiconductor layers, comprising P+ or N+ silicon. The material 181 forms a vertical bit line and the material 183 forms a horizontal source line.
The material 182 is a lightly doped semiconductor, comprising material such as P- or N- silicon. The semiconductor layer 182 has the opposite type of doping as the materials 181 and 183. As shown in FIG. 25B, the material 182 forms a floating body of the cell. This results in a floating-body memory cell.
In another embodiment, the material 182 is an intrinsic semiconductor material, such as silicon. The materials 181 and 183 are heavily doped semiconductor materials, such as P+ or N+ silicon. The materials 181 and 183 have the opposite type of doping. This forms a tunnel field effect transistor (TFET) type of memory cell.
The cell comprises only one gate 184. The gate 184 is connected to a word line. Also shown is a gate dielectric layer 185 comprising material, such as gate oxide or high-K material, such as HfO2. Channel regions 188a and 188b are also shown.
An insulating layer 187 comprises material, such as oxide to prevent the short of material 181 and 183. In one embodiment, a conductor core 189 comprising material, such as metal, is formed in the center of the vertical bit line 181 to reduce the bit line resistance. In one embodiment, the conductor layer 189 is eliminated without affecting the function of the cell.
FIGS. 26A-G shows simplified key process steps of another embodiment of a floating body cell “AND” array according to the invention.
FIG. 26A comprises an insulating layer 801, such as oxide, and a P- or N- silicon or polysilicon layer 802. A sacrificial material layer is deposited on top of the silicon or polysilicon layer 802 and pattern-etched to form the pattern features 803a to 803c.
FIG. 26B shows how regions 804a to 804d are implanted or diffused with the opposite type of doping of the silicon or polysilicon layer 802 by using the sacrificial layer features 803a to 803c as masks. This forms N+ or P+ silicon or polysilicon strips 804a to 804d. The even and odd strips are bit lines and source lines, respectively. It should be noted that the junction of the doping shall reach the insulating layer 801, thus it forms isolated P- or N- silicon or polysilicon strips 805a to 805c.
FIG. 26C shows how an insulating layer, such as oxide, is deposited and etched back to form individual strips 806a to 806d. In another embodiment, the insulator strips are formed by using a chemical mechanical planarization (CMP) process to remove the top portion of the insulating layer.
FIG. 26D shows how the sacrificial material layer 803a to 803c are selectively etched.
FIG. 26E shows how a thin gate dielectric layer 807 comprising material, such as oxide, and a gate material layer 808 comprising material, such as metal or polysilicon, are deposited.
FIG. 26F shows how the gate material layer 808 and the gate dielectric layer 807 are pattern-etched to form the word lines. In one embodiment, the materials 808a and 808b are hard masks or photoresists.
FIG. 26G shows how the P- or N- silicon or polysilicon layers 805a to 805c are self-align etched by using the hard masks 808a and 808b. This forms P- or N- silicon or polysilicon floating bodies 805aʹ to 805cʹ.
While exemplary embodiments of the present invention have been shown and described, it will be obvious to those with ordinary skills in the art that based upon the teachings herein, changes and modifications may be made without departing from the exemplary embodiments and their broader aspects. Therefore, the appended claims are intended to encompass within their scope all such changes and modifications as are within the true spirit and scope of the exemplary embodiments of the present invention.