Abstract: Electrically erasable programmable “read-only” memory (EEPROM) cells in an integrated circuit, and formed by a single polysilicon level. The EEPROM cell consists of a coupling capacitor and a combined read transistor and tunneling capacitor. The capacitance of the coupling capacitor is much larger than that of the tunneling capacitor. In one embodiment, field oxide isolation structures isolate the devices from one another; a lightly-doped region at the source of the read transistor improves breakdown voltage performance. In another embodiment, trench isolation structures and a buried oxide layer surround the well regions at which the coupling capacitor and combined read transistor and tunneling capacitor are formed.

Abstract: Electrically erasable programmable “read-only” memory (EEPROM) cells in an integrated circuit, and formed by a single polysilicon level. The EEPROM cell consists of a coupling capacitor and a combined read transistor and tunneling capacitor. The capacitance of the coupling capacitor is much larger than that of the tunneling capacitor. In one embodiment, field oxide isolation structures isolate the devices from one another; a lightly-doped region at the source of the read transistor improves breakdown voltage performance. In another embodiment, trench isolation structures and a buried oxide layer surround the well regions at which the coupling capacitor and combined read transistor and tunneling capacitor are formed.

Abstract: Electrically erasable programmable “read-only” memory (EEPROM) cells in an integrated circuit, and formed by a single polysilicon level. The EEPROM cell consists of a coupling capacitor and a combined read transistor and tunneling capacitor. The capacitance of the coupling capacitor is much larger than that of the tunneling capacitor. In one embodiment, field oxide isolation structures isolate the devices from one another; a lightly-doped region at the source of the read transistor improves breakdown voltage performance. In another embodiment, trench isolation structures and a buried oxide layer surround the well regions at which the coupling capacitor and combined read transistor and tunneling capacitor are formed.

Abstract: A single-poly EEPROM memory device comprises source and drain regions in a semiconductor body, a floating gate overlying a portion of the source and drain regions, which defines a source-to-floating gate capacitance and a drain-to-floating gate capacitance, wherein the source-to-floating gate capacitance is substantially greater than the drain-to-floating gate capacitance. The source-to-floating gate capacitance is, for example, at least about three times greater than the drain-to-floating gate capacitance to enable the memory device to be electrically programmed or erased by applying a potential between a source electrode and a drain electrode without using a control gate.

Abstract: Electrically erasable programmable “read-only” memory (EEPROM) cells in an integrated circuit, and formed by a single polysilicon level. The EEPROM cell consists of a coupling capacitor and a combined read transistor and tunneling capacitor. The capacitance of the coupling capacitor is much larger than that of the tunneling capacitor. In one embodiment, field oxide isolation structures isolate the devices from one another; a lightly-doped region at the source of the read transistor improves breakdown voltage performance. In another embodiment, trench isolation structures and a buried oxide layer surround the well regions at which the coupling capacitor and combined read transistor and tunneling capacitor are formed.

Abstract: Electrically erasable programmable “read-only” memory (EEPROM) cells in an integrated circuit, and formed by a single polysilicon level. The EEPROM cell consists of a coupling capacitor and a combined read transistor and tunneling capacitor. The capacitance of the coupling capacitor is much larger than that of the tunneling capacitor. In one embodiment, field oxide isolation structures isolate the devices from one another; a lightly-doped region at the source of the read transistor improves breakdown voltage performance. In another embodiment, trench isolation structures and a buried oxide layer surround the well regions at which the coupling capacitor and combined read transistor and tunneling capacitor are formed.

Abstract: A single-poly EEPROM memory device comprises a control gate isolated within a well of a first conductivity type in a semiconductor body of a second conductivity type, first and second tunneling regions isolated from one another within respective wells of the first conductivity type in the semiconductor body, a read transistor isolated within a well of the first conductivity type, and a floating gate overlying a portion of the control gate, the read transistor, and the first and second tunneling regions. The memory device is configured to be electrically programmed by changing a charge on the floating gate that changes the device threshold voltage. In one embodiment, the memory device is configured to be electrically programmed by applying a first potential between the first and second tunneling regions, and a second potential to the control gate, the second potential having a value less than the first potential.

Abstract: A test structure which can be used to detect residual conductive material such as polysilicon which can result from an under etch comprises a PMOS transistor and an OTP EPROM floating gate device. By testing the devices using different testing parameters, it can be determined whether residual conductive material remains subsequent to an etch, and where the residual conductive material is located on the device. A method for testing a semiconductor device using the test structure is also described.

Abstract: A single-poly EEPROM memory device comprises a control gate isolated within a well of a first conductivity type in a semiconductor body of a second conductivity type, first and second tunneling regions isolated from one another within respective wells of the first conductivity type in the semiconductor body, a read transistor isolated within a well of the first conductivity type, and a floating gate overlying a portion of the control gate, the read transistor, and the first and second tunneling regions. The memory device is configured to be electrically programmed by changing a charge on the floating gate that changes the device threshold voltage. In one embodiment, the memory device is configured to be electrically programmed by applying a first potential between the first and second tunneling regions, and a second potential to the control gate, the second potential having a value less than the first potential.

Abstract: A test structure which can be used to detect residual conductive material such as polysilicon which can result from an under etch comprises a PMOS transistor and an OTP EPROM floating gate device. By testing the devices using different testing parameters, it can be determined whether residual conductive material remains subsequent to an etch, and where the residual conductive material is located on the device. A method for testing a semiconductor device using the test structure is also described.

Abstract: A single-poly EEPROM memory device comprises a control gate isolated within a well of a first conductivity type in a semiconductor body of a second conductivity type, first and second tunneling regions isolated from one another within respective wells of the first conductivity type in the semiconductor body, a read transistor isolated within a well of the first conductivity type, and a floating gate overlying a portion of the control gate, the read transistor, and the first and second tunneling regions. The memory device is configured to be electrically programmed by changing a charge on the floating gate that changes the device threshold voltage. In one embodiment, the memory device is configured to be electrically programmed by applying a first potential between the first and second tunneling regions, and a second potential to the control gate, the second potential having a value less than the first potential.

Abstract: An array structure of single-level poly NMOS EEPROM memory cells and method of operating the array is discussed implemented in a higher density embedded EEPROM layout that eliminates the use of high voltage transistors from the array core region. If they are utilized, the high voltage transistors are moved to row and column drivers in the periphery region to increase array density with little or no added process complexity to allow economic implementation of larger embedded SLP EEPROM arrays. During program or erase operations of the array, the method provides a programming voltage for the selected memory cells of the array, and a half-write (e.g., mid-level) voltage to the remaining unselected memory cells to avoid disturbing the unselected memory cells of the array.

Abstract: A single-poly EEPROM memory device comprises source and drain regions in a semiconductor body, a floating gate overlying a portion of the source and drain regions, which defines a source-to-floating gate capacitance and a drain-to-floating gate capacitance, wherein the source-to-floating gate capacitance is substantially greater than the drain-to-floating gate capacitance. The source-to-floating gate capacitance is, for example, at least about three times greater than the drain-to-floating gate capacitance to enable the memory device to be electrically programmed or erased by applying a potential between a source electrode and a drain electrode without using a control gate.

Abstract: Methods fabricate DEMOS devices having varied channel lengths and substantially similar threshold voltages. A threshold voltage is selected for first and second devices. First and second well regions are formed. First and second drain extension regions are formed within the well regions. First and second back gate regions are formed within the well regions according to the selected threshold voltage. First and second gate structures are formed over the first and second well regions having varied channel lengths. A first source region is formed in the first back gate region and a first drain region is formed in the first drain extension region. A second source region is formed in the second back gate region and a second drain region is formed in the drain extension region.

Abstract: A one time programmable (OTP) electrically programmable read only memory (EPROM) transistor (100) having an increased breakdown voltage (BVdss) is disclosed. The increased breakdown voltage reduces the probability that the OTP EPROM (100) will breakdown during a programming operation by maintaining a breakdown voltage above a programming voltage. The breakdown voltage is, at least partially, increased by forming a p-doped region (140) within a semiconductor substrate (102), and forming a drain region (166) of the OTP EPROM (100) within the p-doped region (140).

Abstract: The present invention facilitates semiconductor fabrication by maintaining uniform thickness of a gate oxide layer (112) during the oxide growth process of non-volatile memory devices (100). The uniform thickness of a gate oxide layer (112) is obtained by defining the boundaries of the source and drain areas (110) of a memory device (100) with the source/drain dopant masking and implanting operation. If an isolation barrier (108) is present it is kept a minimum safe distance (130) away from the periphery of the conductive gate layer (114) to avoid birds-beak regions (30) responsible for non-uniform gate oxide growth. As a result, the corresponding charge losses and weak cells are mitigated, thereby facilitating the fabrication of more reliable memory cells (100). Because a more uniform gate oxide thickness (112) is used in association with the memory cells (100), a single significantly thinner gate oxide layer (114) may be employed throughout the memory device (100).

Abstract: An integrated circuit drain extension transistor. A transistor gate (72) is formed over a CMOS n-well region (10). A transistor source extension region (50), and drain extension region (52) are formed in the CMOS well region (10). A transistor region (90) is formed in the source extension region 50 and a transistor drain region 92 is formed between two drain alignment structures (74), (76) in the drain extension region (52).

Abstract: An integrated circuit drain extension transistor. A transistor gate (72) is formed over a CMOS n-well region (10). A transistor source extension region (50), and drain extension region (52) are formed in the CMOS well region (10). A transistor region (90) is formed in the source extension region 50 and a transistor drain region 92 is formed between two drain alignment structures (74), (76) in the drain extension region (52).