Abstract: A non-volatile electrically erasable programmable read only memory (EEPROM) capable of storing two bit of information having a nonconducting charge trapping dielectric, such as silicon nitride, sandwiched between two silicon dioxide layers acting as electrical insulators is disclosed. The invention includes a method of programming, reading and erasing the two bit EEPROM device. The nonconducting dielectric layer functions as an electrical charge trapping medium. A conducting gate layer is placed over the upper silicon dioxide layer. A left and a right bit are stored in physically different areas of the charge trapping layer, near left and right regions of the memory cell, respectively. Each bit of the memory device is programmed in the conventional manner, using hot electron programming, by applying programming voltages to the gate and to either the left or the right region while the other region is grounded.

Abstract: A non-volatile electrically erasable programmable read only memory (EEPROM) capable of storing two bit of information having a non-conducting charge trapping dielectric, such as silicon nitride, sandwiched between two silicon dioxide layers acting as electrical insulators is disclosed. The invention includes a method of programming, reading and erasing the two bit EEPROM device. The non-conducting dielectric layer functions as an electrical charge trapping medium. A conducting gate layer is placed over the upper silicon dioxide layer. A left and a right bit are stored in physically different areas of the charge trapping layer, near left and right regions of the memory cell, respectively. Each bit of the memory device is programmed in the conventional manner, using hot electron programming, by applying programming voltages to the gate and to either the left or the right region while the other region is grounded.

Abstract: A method of fabricating an oxide-nitride-oxide (ONO) layer in a memory cell to retain charge well in the nitride layer includes the steps of forming a bottom oxide layer on a substrate, depositing a nitride layer and oxidizing a top oxide layer, thereby causing oxygen to be introduced into the nitride layer. Another method includes the steps of forming a bottom oxide layer on a substrate, depositing a nitride layer and oxidizing a portion of a top oxide layer, thereby causing oxygen to be introduced into the nitride layer and depositing a remaining portion of the top oxide layer, thereby assisting in controlling the amount of oxygen introduced into the nitride layer. A further method includes the steps of forming a bottom oxide layer on a substrate, depositing a nitride layer, depositing a portion of a top oxide layer and oxidizing a remaining portion of the top oxide layer, thereby causing oxygen to be introduced into the nitride layer.

Abstract: A die for a memory array may store Flash and EEPROM bits in at least one Nitride Read Only Memory (NROM) array. Each array may store Flash, EEPROM or both types of bits.

Abstract: A die for a memory array may store Flash and EEPROM bits in at least one Nitride Read Only Memory (NROM) array. Each array may store Flash, EEPROM or both types of bits.

Abstract: A non-volatile electrically erasable programmable read only memory (EEPROM) capable of storing two bit of information having a non-conducting charge trapping dielectric, such as silicon nitride, sandwiched between two silicon dioxide layers acting as electrical insulators is disclosed. The invention includes a method of programming, reading and erasing the two bit EEPROM device. The non-conducting dielectric layer functions as an electrical charge trapping medium. A conducting gate layer is placed over the upper silicon dioxide layer. A left and a right bit are stored in physically different areas of the charge trapping layer, near left and right regions of the memory cell, respectively. Each bit of the memory device is programmed in the conventional manner, using hot electron programming, by applying programming voltages to the gate and to either the left or the right region while the other region is grounded.

Abstract: A method of fabricating an oxide-nitride-oxide (ONO) layer in a memory cell to retain charge well in the nitride layer includes the steps of forming a bottom oxide layer on a substrate, depositing a nitride layer and oxidizing a top oxide layer, thereby causing oxygen to be introduced into the nitride layer. Another method includes the steps of forming a bottom oxide layer on a substrate, depositing a nitride layer and oxidizing a portion of a top oxide layer, thereby causing oxygen to be introduced into the nitride layer and depositing a remaining portion of the top oxide layer, thereby assisting in controlling the amount of oxygen introduced into the nitride layer. A further method includes the steps of forming a bottom oxide layer on a substrate, depositing a nitride layer, depositing a portion of a top oxide layer and oxidizing a remaining portion of the top oxide layer, thereby causing oxygen to be introduced into the nitride layer.

Abstract: A method of fabricating an oxide-nitride-oxide (ONO) layer in a memory cell to retain charge well in the nitride layer includes the steps of forming a bottom oxide layer on a substrate, depositing a nitride layer and oxidizing a top oxide layer, thereby causing oxygen to be introduced into the nitride layer. Another method includes the steps of forming a bottom oxide layer on a substrate, depositing a nitride layer and oxidizing a portion of a top oxide layer, thereby causing oxygen to be introduced into the nitride layer and depositing a remaining portion of the top oxide layer, thereby assisting in controlling the amount of oxygen introduced into the nitride layer. A further method includes the steps of forming a bottom oxide layer on a substrate, depositing a nitride layer, depositing a portion of a top oxide layer and oxidizing a remaining portion of the top oxide layer, thereby causing oxygen to be introduced into the nitride layer.

Abstract: A non-volatile memory device includes a plurality of word line areas each separated from its neighbor by a contact area, an oxide-nitride-oxide (ONO) layer within the word line areas and at least partially within the contact areas and protective elements, generated when spacers are formed in the periphery area, to protect silicon under the ONO layer in the contact areas. A non-volatile memory device includes a plurality of word line areas each separated from its neighbor by a contact area and bitline oxides whose height:distance aspect ratio (T:D) is at least 25% greater than the maximum height:distance (Tg:Dg) ratio of gate electrodes in the CMOS periphery to ensure remnants of sidewall material between bitlines after sidewall spacer etch, thus protecting silicon in a subsequent word line salicidation step.

Abstract: A method for protecting NROM devices from charge damage during process steps, the method including providing X-decoder structure for word line connections, wherein each word line is connected to a pair of transistors, a PMOS transistor and an NMOS transistor the PMOS transistors sharing a common deep N well and the NMOS transistors connected to a P well, wherein during negative charging, the NMOS transistors shunt leakage current to ground, and during positive charging, the PMOS transistors shunt leakage current to ground, providing an N+ tap connected to the N well and connecting the N+ tap to a positive voltage clamping device, and connecting all the P wells together to a common P+ tap and connecting the P+ tap to a negative voltage clamping device, wherein during process steps, the negative and positive voltage clamping devices direct leakage current to ground.

Abstract: A method for programming one or more reference cells is described. The reference cell is programmed a predetermined amount, its program state is sensed relative to a prescribed cell on the same die (e.g., a memory cell or a golden bit cell), and the programming process continues until the reference cell fails a preselected read operation. In one preferred embodiment, the memory cell used during the reference cell programming process is the cell in the memory array having the highest native threshold value. In another preferred embodiment, the memory cell used during the reference cell programming process is a native cell that is on-board the die containing the memory array, but not a cell within the memory array.

Abstract: A non-volatile electrically erasable programmable read only memory (EEPROM) capable of storing two bit of information having a non-conducting charge trapping dielectric, such as silicon nitride, sandwiched between two silicon dioxide layers acting as electrical insulators is disclosed. The invention includes a method of programming, reading and erasing the two bit EEPROM device. The non-conducting dielectric layer functions as an electrical charge trapping medium. A conducting gate layer is placed over the upper silicon dioxide layer. A left and a right bit are stored in physically different areas of the charge trapping layer, near left and right regions of the memory cell, respectively. Each bit of the memory device is programmed in the conventional manner, using hot electron programming, by applying programming voltages to the gate and to either the left or the right region while the other region is grounded.

Abstract: An NVM cell such as an NROM cell is formed using a portion of one ONO stack and an adjacent portion of a neighboring NROM stack. A gate structure is formed between (and atop) the two ONO portions, or “strips” (or “stripes”). This provides having two physically separated charge storage regions (nitride “strips”, or “stripes”) in each memory cell.

Abstract: Programming a NVM memory cell such as an NROM cell by using hot hole injection (HHI), followed by channel hot electron (CHE) injection. CHE injection increases the threshold voltage (Vt) of bits of memory cells that were disturbed (unnecessarily programmed) in HHI programming step. Page Write may be performed using a combination of only HHI, followed by CHE without any Erase.

Abstract: Operating NVM memory cell such as an NROM cell by using a combination of Fowler-Nordheim tunneling (FNT), hot hole injection (HHI), and channel hot electron (CHE) injection. In the FNT erase step, only a few cells may be verified, and in the CHE second programming step, the threshold voltage of those cells which were not fully erased in the FNT erase step is increased to a high threshold voltage level (ERS state).

Abstract: A method includes changing a read reference level for reading a group of memory cells as a function of changes in a threshold voltage distribution of a different group of memory cells. The changing step includes determining a history read reference level for correct reading of at least one history cell, selecting a memory read reference level according to the first read reference level, and reading non-volatile memory array cells associated with the at least one history cell using the memory read reference level.

Abstract: A method for creating a non-volatile memory array includes generating removable mask columns to define bit lines, implanting bit lines into the substrate at least between the columns, depositing oxide filler over the bit lines, removing the mask columns, depositing a polysilicon layer over the array and etching the polysilicon layer into word lines. The polysilicon extends at least into spaces left behind by the removed mask columns. The method also includes performing a dual work integration doping after the word line patterning.

Abstract: Secondary electron injection (SEI) is used for programming NVM cells having separate charge storage areas in an ONO layer, such as NROM cells. Various combinations of low wordline voltage (Vwl), negative substrate voltabe (Vb), and shallow and deep implants facilitate the process. Second bit problems may be controlled, and retention and punchthrough may be improved. Lower SEI programming current may result in relaxed constraints on bitine resistance, number of contacts required, and power supply requirements.

Abstract: A method for reading a bit of a memory cell in a non-volatile memory (NVM) cell array, the method comprising providing a memory cell comprising a bit to be read and at least one other bit not to be read, and reading the bit to be read with respect to a multi-bit reference cell, the reference cell comprising a first bit at a first non-ground programmed state and a second bit at a second non-ground programmed state. Compared with the prior art, the present invention may enable achieving an improved sensing accuracy together with improved read disturb immunity.

Abstract: A non-volatile memory chip has word lines spaced a sub-F (sub-minimum feature size F) width apart with extensions of the word lines in at least two transition areas. Neighboring extensions are spaced at least F apart. The present invention also includes a method for word-line patterning of a non-volatile memory chip which includes generating sub-F word lines with extensions in transition areas for connecting to peripheral transistors from mask generated elements with widths of at least F.