Abstract: A semiconductor device includes a non-volatile memory, such as an electrically erasable programmable read only memory (EEPROM) array of memory cells. The memory is arranged as an array of cells in rows and columns. P-well regions of the array are spaced apart and electrically isolated by shallow trench features. The cells of each column are positioned within a respective isolated p-well region. Control gates of sequentially corresponding memory cells in columns of the array are electrically coupled by common wordlines. Bitlines electrically couple drain regions of each memory cell in the respective columns of the memory cell array. Source lines electrically couple source regions of each memory cell in the respective columns of the array. The source lines and at least one memory cell in each column of the array are electrically coupled to the p-well region corresponding to the column of the source line and cell.

Abstract: A series select transistor and a source select transistor are connected in series at the end of a NAND string of floating gate data storage transistors. The floating gates, the series select gate, and the source select gate are all preferably formed of polysilicon. The same tunnel oxide layer is used as gate oxide for the series select transistor and source select transistor as well as for the floating gate data storage transistors. Two layers of polysilicon in the series select gate and the source select gates are tied together. The series select transistor is tied to the last transistor in the NAND string. The source select transistor is tied to the array Vss supply. In order to program inhibit a specific NAND cell during the programming of another NAND cell, the gate of the series select transistor is raised to Vcc, while the gate of the source select transistor is held to ground.

Abstract: The present invention provides a method of verifying that all flash EEPROM transistors in a NAND string are properly erased without overerasing by applying a bias voltage to the source of the bottom select gate of the NAND array and applying a non-negative erase verify voltage to the control gates of each transistor during an erase verify. The bias voltage is at least equal to the erased threshold voltage of the worst case transistor to ensure proper erase verification. If all transistors are not erased, then another erase operation is performed. Erasing is repeated until the erase verify operation indicates that all transistors are properly erased. By erasing and verifying according to the present invention, the NAND array is completely and properly erased while minimizing overerasing the array.

Abstract: A series select transistor and a source select transistor are connected in series at the end of a NAND string of floating gate data storage transistors. The floating gates, the series select gate, and the source select gate are all preferably formed of polysilicon. The same tunnel oxide layer is used as gate oxide for the series select transistor and source select transistor as well as for the floating gate data storage transistors. Two layers of polysilicon in the series select gate and the source select gates are tied together. The series select transistor is tied to the last transistor in the NAND string. The source select transistor is tied to the array Vss supply. In order to program inhibit a specific NAND cell during the programming of another NAND cell, the gate of the series select transistor is raised to Vcc, while the gate of the source select transistor is held to ground.

Abstract: A series select transistor and a source select transistor are connected in series at the end of a NAND string of floating gate data storage transistors. The floating gates, the series select gate, and the source select gate are all preferably formed of polysilicon. The same tunnel oxide layer is used as gate oxide for the series select transistor and source select transistor as well as for the floating gate data storage transistors. Two layers of polysilicon in the series select gate and the source select gates are tied together. The series select transistor is tied to the last transistor in the NAND string. The source select transistor is tied to the array Vss supply. In order to program inhibit a specific NAND cell during the programming of another NAND cell, the gate of the series select transistor is raised to Vcc, while the gate of the source select transistor is held to ground.

Abstract: According to an aspect of the embodiments, the block decoder control circuits which drive the pass transistors for the word lines for a flash memory array are driven with a control voltage that is regulated to be one enhancement transistor's threshold voltage higher than the highest voltage that is actually driven onto the word lines. According to another aspect of some of the embodiments, the block decoder control circuits are implemented with transistors having a very low threshold voltage. According to yet another aspect of some of the embodiments, a special series connection is used to prevent any leakage current through the block decoder control circuit from the high voltage generating charge pumps which might otherwise result from the use of low threshold voltage transistors. In the special series connection, any leakage current occurs from the supply voltage source rather than from the high voltage generating charge pumps.

Abstract: The present invention is a semiconductor device and a method of providing such a semiconductor device which allows a high junction breakdown voltage and a high field turn on voltage, while allowing the field oxide thickness to be limited and being independent of a misalignment of the mask. A method in accordance with the present invention for providing a semiconductor device including a field oxide, the field oxide including a field oxide boundary wherein the field oxide is located within the boundary, the method comprising the step of implanting a first implant area into the substrate, including areas proximate indistance to a junction area, the first area being implanted with a first implant concentration and implanting a second implant area distal to the junction area, the second implant area being implanted with a second implant concentration, wherein the depth of the implant is controlled by the energy level, wherein the implant of the second implant area is independent of a misalignment of a mask.

Abstract: According to an aspect of the embodiments, the block decoder control circuits which drive the pass transistors for the word lines for a flash memory array are driven with a control voltage that is regulated to be one enhancement transistors threshold voltage higher than the highest voltage that is actually driven onto the word lines. According to another aspect of some of the embodiments, the block decoder control circuits are implemented with transistors having a very low threshold voltage. According to yet another aspect of some of the embodiments, a special series connection is used to prevent any leakage current through the block decoder control circuit from the high voltage generating charge pumps which might otherwise result from the use of low threshold voltage transistors. In the special series connection, any leakage current occurs from the supply voltage source rather than from the high voltage generating charge pumps.

Abstract: The present invention facilitates programming of selected floating gate devices while successfully inhibiting the programming of unselected devices, without the need for growing multiple thicknesses of oxides. The preferred embodiment of the present invention utilizes a multiple select gate device. In particular, the select gate device is preferably a dual floating gate device rather than the conventional transistor (or device functioning as a conventional transistor) used in the current Flash memory systems as a select gate device.

Abstract: The present invention is a system and method which allows random programming and avoids the problem with band-to-band tunneling current discussed above. In particular, the present invention applies a predetermined voltage along the wordlines adjacent to the programming wordline. A method of programming in a Flash memory system includes providing a first wordline coupled with a first device desired to be programmed, the first wordline also coupled with a second device desired to be program inhibited; electrically isolating the second device; programming the first device; and programming a third device coupled with a second wordline, the second wordline not being adjacent to the first wordline.

Abstract: A non-volatile memory device is provided having various electrical couplings for maximizing over-erased correction of that device. Over-erased devices within an array can be corrected in bulk, simultaneous with all other devices within the array. Bulk correction of an array of over-erased device is carried forth in a convergence technique which utilizes higher floating gate injection currents. Negatively biased substrate causes an enhancement in the injection current and resulting correction capability of the convergence operation. Moreover, convergence can be carried out with a lesser positive voltage upon the drain region, which implies a reduction in the source-to-drain currents as well as substrate currents during the convergence operation. Accordingly, only over-erased transistors receive sufficient turn-on during convergence, while all other transistors remain off.