Abstract: An electrically erasable programmable logic device (EEPLD) includes a P type semiconductor substrate. An N type well is formed on the P type semiconductor substrate. A first PMOS transistor is formed on the N well. The first PMOS transistor comprises a floating gate, a first P+ doped region serving as a drain of the first PMOS transistor, and a P− doped region encompassing an N+ doped region for erasing the first PMOS transistor. A second PMOS transistor is also formed on the N well and serially connected to the first PMOS transistor. The first P+ doped region functions as a source of the second PMOS transistor, and the second PMOS transistor further comprises a select gate and a second P+ doped region serving as a drain of the second PMOS transistor.

Abstract: The present invention proposes a novel structure of nonvolatile memory. The aspect of the present invention includes two serially connected PMOS transistor. The characteristic of the devices is that bias is not necessary to apply to the floating gate during the programming mode. Thus, the control gate is omitted for the structure or layout, thereby saving the space for making the control gate. The present invention may “automatically inject” carrier into floating gate for programming the status of the device.

Abstract: A method for manufacturing a flash device having a trench source line comprises providing a semiconductor substrate. A pad oxide is formed on a substrate, then forming a nitride layer on the pad oxide. The nitride layer and the pad oxide layer are patterned then etching the substrate to form a trench in the substrate. An ion implantation is performed to dope ions into the substrate under the trench to form the trench source line. Next, refilling material is refilled into the trench, followed by performing chemical mechanical polishing to remove a portion of the refilling material to the substrate. A gate dielectric layer, a first doped conductive layer, an inter conductive dielectric layer, a second conductive layer are formed. The first conductive layer, the second conductive layer and the inter conductive dielectric layer are etched to form gate structure. Subsequently, source and drain regions are formed by ion implantation and halo-doped region is formed under the drain regions by ion implantation.

Abstract: A contactless channel write/erase flash memory cell structure and its fabricating method for increasing the level of integration is disclosed. The present invention utilizes a buried diffusion method to form an N+-doped region that acts as a drain of the flash memory cell and a P-doped region underneath an oxide layer. The N+-doped region and the P-doped region extend to in a bit line direction and a metal contact is used to connect the two away from any of the N+-doped region and the P-doped region of the flash memory cell for decreasing the numbers of the metal contacts in the flash memory cell and reducing dimensions of the device.

Abstract: A contactless channel write/erase flash memory cell structure and its fabricating method for increasing the level of integration is disclosed. The present invention utilizes a buried diffusion method to form an N+-doped region that acts as a drain of the flash memory cell and a P-doped region underneath an oxide layer. The N+-doped region and the P-doped region extend to in a bit line direction and a metal contact is used to connect the two away from any of the N+-doped region and the P-doped region of the flash memory cell for decreasing the numbers of the metal contacts in the flash memory cell and reducing dimensions of the device.

Abstract: A nonvolatile semiconductor memory capable of random programming has a semiconductor substrate of a first conductivity type having a memory region, a deep ion well of a second conductivity type located in the semiconductor substrate within the memory region, a shallow ion well of the first conductivity type isolated by an STI layer within the deep ion well, at least one NAND cell block located on the semiconductor substrate within the shallow ion well, and a bit line located over the semiconductor substrate used to provide a first predetermined voltage for the shallow ion well during a data program mode via a conductive plug which electrically connects to the bit line and extends downward to the shallow ion well. Consequently, during a programming operation, only a selected word line is required to have an appropriate voltage applied to it. Thus, the power needed is reduced and access time is shortened.

Abstract: The present invention relates to a structure of an embedded channel write/erase flash memory cell and a fabricating method thereof and, more particularly, to a structure combining CMOS devices and flash memory cells, wherein flash memory cell structures and CMOS devices are simultaneously fabricated on a substrate to reduce the cost and to simplify the process flow. Moreover, CMOS devices capable of performing high-voltage and low-voltage operations are reserved. Therefore, the present invention can not only effectively improve the operating efficiency of flash memory cells and CMOS devices, but its whole volume is also smaller than that obtained by combining separately designed and fabricated CMOS devices and flash memory cells.

Abstract: A pseudo-dynamic operating method and a flash memory cell capable of performing this operating method are disclosed. A parasitic capacitor near the drain terminal of the flash memory can be charged in few microseconds during operation. Interference generated between the floating gate and the source is avoided by using a first oxide layer which is thicker at the interface between floating gate and source and thinner near central part under stacked gate.

Abstract: The present invention relates to a structure of an embedded channel write/erase flash memory cell and a fabricating method thereof and, more particularly, to a structure combining CMOS devices and flash memory cells, wherein flash memory cell structures and CMOS devices are simultaneously fabricated on a substrate to reduce the cost and to simplify the process flow. Moreover, CMOS devices capable of performing high-voltage and low-voltage operations are reserved. Therefore, the present invention can not only effectively improve the operating efficiency of flash memory cells and CMOS devices, but its whole volume is also smaller than that obtained by combining separately designed and fabricated CMOS devices and flash memory cells.

Abstract: The present invention relates to a structure of a low-voltage channel write/erase flash memory cell and a fabricating method thereof, which structure comprises an N-substrate, a deep P-well formed on the substrate, and an N-well formed on the deep P-well. A deep p-type region and a shallow p-type region are ion-implanted in the N-well. The deep p-type region is connected to the shallow p-type region. An n-type region is ion-implanted in the deep p-type region to be electrically shorted with the deep p-type region and be used as a drain. Another n-type region is also ion-implanted at one side of the shallow p-type region to be used as a source.

Abstract: A pseudo-dynamic operating method and a flash memory cell capable of performing this operating method are disclosed. A parasitic capacitor near the drain terminal of the flash memory can be charged in few microseconds during operation. Interference generated between the floating gate and the source is avoided by using a first oxide layer which is thicker at the interface between floating gate and source and thinner near central part under stacked gate.

Abstract: The present invention relates to a structure of a low-voltage channel write/erase flash memory cell and a fabricating method thereof, which structure comprises an N-substrate, a deep P-well formed on the substrate, and an N-well formed on the deep P-well. A deep p-type region and a shallow p-type region are ion-implanted in the N-well. The deep p-type region is connected to the shallow p-type region. An n-type region is ion-implanted in the deep p-type region to be electrically shorted with the deep p-type region and be used as a drain. Another n-type region is also ion-implanted at one side of the shallow p-type region to be used as a source.

Abstract: A flash memory cell with an embedded gate structure capable of storing two bits of information and the operation of such a flash memory cell are provided. A first ion-doped region, serving as a source terminal, is formed in a semiconductor substrate. An embedded gate structure and a second ion-doped region are alternately arranged on the first ion-doped region. The embedded gate structure is surrounded by the first oxide layer, the trapping layer, and the second oxide layer. An insulating layer is formed on the embedded gate structure. A diffusion drain is positioned atop the second ion-doped region and a conductive layer connects with the diffusion drains. The embedded gate structure is isolated from the diffusion drain with the insulating layer. Furthermore, the reading, programming, and erasing operation of the memory cell with two bits of information are provided.

Abstract: The present invention relates to a structure of an embedded channel write/erase flash memory cell and a fabricating method thereof and, more particularly, to a structure combining CMOS devices and flash memory cells, wherein flash memory cell structures and CMOS devices are simultaneously fabricated on a substrate to reduce the cost and to simplify the process flow. Moreover, CMOS devices capable of performing high-voltage and low-voltage operations are reserved. Therefore, the present invention can not only effectively improve the operating efficiency of flash memory cells and CMOS devices, but its whole volume is also smaller than that obtained by combining separately designed and fabricated CMOS devices and flash memory cells.

Abstract: A pseudo-dynamic operating method and a flash memory cell capable of performing this operating method are disclosed. A parasitic capacitor near the drain terminal of the flash memory can be charged in few microseconds during operation. Interference generated between the floating gate and the source is avoided by using a first oxide layer which is thicker at the interface between floating gate and source and thinner near central part under stacked gate.

Abstract: A flash memory cell with an embedded gate structure capable of storing two bits of information and the operation of such a flash memory cell are provided. A first ion-doped region, serving as a source terminal, is formed in a semiconductor substrate. An embedded gate structure and a second ion-doped region are alternately arranged on the first ion-doped region. The embedded gate structure is surrounded by the first oxide layer, the trapping layer, and the second oxide layer. An insulating layer is formed on the embedded gate structure. A diffusion drain is positioned atop the second ion-doped region and a conductive layer connects with the diffusion drains. The embedded gate structure is isolated from the diffusion drain with the insulating layer. Furthermore, the reading, programming, and erasing operation of the memory cell with two bits of information are provided.

Abstract: The present invention provides an embedded type flash memory structure and a method for operating the same. The memory structure of the present invention comprises a first deep doped-region formed on the surface of a semiconductor substrate. A second doped-region is implanted in the first deep doped-region. A plurality of first shallow doped-regions are respectively formed in the second doped-region and the first deep doped-region to be used as drains and sources. A dielectric insulating layer and a poly-silicon gate are stacked above the first deep doped-region between the source and the drain. The present invention also proposes programming, erasing, and reading processes corresponding to the flash memory cell structure.

Abstract: The present invention provides an embedded type flash memory structure and a method for operating the same. The memory structure of the present invention comprises a first deep doped-region formed on the surface of a semiconductor substrate. A second doped-region is implanted in the first deep doped-region. A plurality of first shallow doped-regions are respectively formed in the second doped-region and the first deep doped-region to be used as drains and sources. A dielectric insulating layer and a poly-silicon gate are stacked above the first deep doped-region between the source and the drain. The present invention also proposes programming, erasing, and reading processes corresponding to the flash memory cell structure.

Abstract: A contactless channel write/erase flash memory cell structure and its fabricating method for increasing the level of integration is disclosed. The present invention utilizes a buried diffusion method to form an N+-doped region that acts as a drain of the flash memory cell and a P-doped region underneath an oxide layer. The N+-doped region and the P-doped region extend to in a bit line direction and a metal contact is used to connect the two away from any of the N+-doped region and the P-doped region of the flash memory cell for decreasing the numbers of the metal contacts in the flash memory cell and reducing dimensions of the device.

Abstract: A method of selectively programming an individual memory cell of a non-volatile memory array. The non-volatile memory array is an array of memory cells. Each memory cell is made up of an ONO gate built on a substrate, which also acts as a well. On one side of the gate is a diffusion drain encompassed by a localized well region set in the well. On the other side of the gate is a diffusion source set in the well. When operated, appropriate voltages are applied to the source, the gate, the drain, and the localized well region to program or erase the non-volatile memory. The designed localized well region prevents an induction current in the unselected gates of the array, allowing for better selectivity and performance.