Abstract: A structure and a process for manufacturing semiconductor devices with improved ESD protection for high voltage applications is described. A thick field gate oxide N channel field effect transistor (FET) device with a tunable threshold voltage (Vt) is developed at the input/output to the internal active circuits for the purpose of providing ESD protection for applications in the 9 volt and higher range. The FET threshold voltage determines the ESD protection characteristics. A N-field implant is used to provide a dopant region under the thick oxide gate element which has the effect of modifying the threshold voltage (Vt) of this device enabling the device turn-on to be “tuned” to more closely match the application requirements of the internal semiconductor circuits. The gate electrical contact is completed by using either a metal gate electrode or polysilicon gate element.

Abstract: A structure and a process for manufacturing semiconductor devices with improved ESD protection for high voltage applications is described. A thick field gate oxide N channel field effect transistor (FET) device with a tunable threshold voltage (Vt) is developed at the input/output to the internal active circuits for the purpose of providing ESD protection for applications in the 9 volt and higher range. The FET threshold voltage determines the ESD protection characteristics. A N-field implant is used to provide a dopant region under the thick oxide gate element which has the effect of modifying the threshold voltage (Vt) of this device enabling the device turn-on to be “tuned” to more closely match the application requirements of the internal semiconductor circuits. The gate electrical contact is completed by using either a metal gate electrode or polysilicon gate element.

Abstract: A structure and a process for manufacturing semiconductor devices with improved ESD protection for high voltage applications is described. A thick field gate oxide N channel field effect transistor (FET) device with a tunable threshold voltage (Vt) is developed at the input/output to the internal active circuits for the purpose of providing ESD protection for applications in the 9 volt and higher range. The FET threshold voltage determines the ESD protection characteristics. A N-field implant is used to provide a dopant region under the thick oxide gate element which has the effect of modifying the threshold voltage (Vt) of this device enabling the device turn-on to be “tuned” to more closely match the application requirements of the internal semiconductor circuits. The gate electrical contact is completed by using either a metal gate electrode or polysilicon gate element.

Abstract: The invention provides a method for forming a ROM cell surface implant region using a PLDD implant. A semiconductor structure is provided comprising a substrate having isolation structures thereon, which separate and electrically isolating a first area having a P-well formed in the substrate and a gate over the substrate, a second area having a N-well formed in the substrate and a gate over the substrate, and a third area having P-well and buried N+ regions formed in the substrate with second isolation structures overlying the buried N+ regions. A photoresist mask is formed exposing the first area, and impurity ions are implanted to form n-type lightly doped source and drain regions. The photoresist mask is removed and a new (PLDD/ROM) photoresist mask is formed exposing the second area and the third area. Impurity ions are implanted to simultaneously form p-type lightly doped source and drain regions and a ROM cell surface implant region region. The PLDD/ROM photoresist mask is then removed.

Abstract: A method and means for testing binary code devices, such as ROMs, for correct coding during processing with the Process Control Machine (PCM) for the fabrication process by applying it on the scribe-line built-in binary code devices, and using the testing program to measure the threshold voltage VTN of the code devices and convert the binary signal sensed to a decimal number to identify the ROM code id. After finishing wafer processing and PCM testing, the real ROM code id that has been fabricated can be read from the PCM testing report.

Abstract: A method for forming a p-type halo implant as ROM cell isolation in a flat-cell mask ROM process is described. A P-well is formed within a semiconductor substrate and an oxide layer is formed overlying a surface of the substrate. A photomask is formed overlying the oxide layer wherein openings are left within the photomask exposing portions of the oxide layer. First, ions are implanted through the exposed portions of the oxide layer into the underlying semiconductor substrate whereby buried bit lines are formed. Thereafter, second ions are implanted through the exposed portions of the oxide layer whereby halo regions are formed encompassing the buried bit lines. The halo regions provide ROM isolation and punch-through protection for the buried bit lines. Thereafter, the photomask is removed and fabrication of flat-cell mask ROM device is completed.

Abstract: The present invention provides a method of manufacturing a read only memory that is code implanted late in the process after the first level metal thus reducing the turn around time to ship a customer order. The invention comprising the steps of: forming bit lines 125 and word lines 160 in a cell area 12A and MOS transistors in a peripheral area 13 of an integrated circuit; forming a first dielectric layer 300 over the surface; etching back the first dielectric layer 300 in the cell area; forming metal contacts 700 to the MOS devices in the peripheral areas 13; forming the second dielectric layer 320 over the resultant surface, storing the integrated circuit; and programming the ROM region 12A by the steps of forming a Code mask 340 with openings 340A from over portions of word lines in the cell area and implanting impurities through the openings 340A into substrate under the selected word lines 160 thereby programming the ROM device.