Patent application number | Description | Published |
20080224200 | METHOD OF FABRICATING NAND-TYPE FLASH EEPROM WITHOUT FIELD OXIDE ISOLATION - Methods are described for fabricating NAND-type EEPROMs without field oxide isolation. P+ implantations are employed to isolate adjacent memory cells. | 09-18-2008 |
20090011594 | Methods of Trench and Contact Formation in Memory Cells - Methods of contact formation and memory arrays formed using such methods, which methods include providing a substrate having a contacting area; forming a plurality of line-shape structures extending in a first direction; forming a hard mask spacer beside the line-shape structure; forming an insulating material layer above the hard mask spacer; forming a contiguous trench in the insulating material layer extending in a second direction different from the first direction and exposing the contacting area; and forming a conductive line in the trench to contact the contacting area. | 01-08-2009 |
20090091983 | NON-VOLATILE MEMORY STRUCTURE AND ARRAY THEREOF - A non-volatile memory structure including a substrate, stacked patterns and stress patterns is provided. The stacked patterns are disposed on the substrate. Each of the stacked patterns includes a charge storage structure and a gate from bottom to top. Here, the charge storage structure at least includes a charge storage layer. The stress patterns are disposed on the substrate between the two adjacent stacked patterns, respectively. | 04-09-2009 |
20090213656 | FLASH MEMORY HAVING INSULATING LINERS BETWEEN SOURCE/DRAIN LINES AND CHANNELS - A memory array comprises a semiconductor body having a plurality of trenches aligned generally in parallel. The trenches contain semiconductor material, such as doped amorphous silicon, and act as source/drain lines for the memory array. Insulating liners lie between the semiconductor material within the trenches and the semiconductor body. A plurality of word lines overlie the plurality of trenches and channel regions in the semiconductor body in an array of cross points. Charge trapping structures lie between the word lines and the channel regions at the cross points, providing an array of flash memory cells. The charge trapping structures comprise dielectric charge trapping structures adapted to be programmed and erased to store data. A method for manufacturing such devices includes patterning and forming the sources/drain lines with insulating liners prior to formation of the charge trapping structure over the channel regions. | 08-27-2009 |
20090276737 | TOOL FOR CHARGE TRAPPING MEMORY USING SIMULATED PROGRAMMING OPERATIONS - A method for simulating operation of a charge trapping memory cell which computes the amount of charge trapped by determining first tunneling current through the tunneling layer, determining second tunneling current out of the charge trapping layer to the gate, determining third tunneling current escaping from traps in the charge trapping layer and tunneling out to the gate, and integrating said tunneling currents over a time interval. A change in threshold voltage can be computed for a transistor including the charge trapping structure. The parameter set can include only physical parameters, including layer thickness, band offsets and dielectric constants. | 11-05-2009 |
20100120210 | FLASH MEMORY HAVING INSULATING LINERS BETWEEN SOURCE/DRAIN LINES AND CHANNELS - A memory array comprises a semiconductor body having a plurality of trenches aligned generally in parallel. The trenches contain semiconductor material, such as doped amorphous silicon, and act as source/drain lines for the memory array. Insulating liners lie between the semiconductor material within the trenches and the semiconductor body. A plurality of word lines overlie the plurality of trenches and channel regions in the semiconductor body in an array of cross points. Charge trapping structures lie between the word lines and the channel regions at the cross points, providing an array of flash memory cells. The charge trapping structures comprise dielectric charge trapping structures adapted to be programmed and erased to store data. A method for manufacturing such devices includes patterning and forming the sources/drain lines with insulating liners prior to formation of the charge trapping structure over the channel regions. | 05-13-2010 |
20120008363 | Diode-Less Array for One-Time Programmable Memory - A one-time programmable memory array includes a first row conductor extending in a first row direction and disposed at a first elevation, a second row conductor extending in a second row direction and disposed at a second elevation and a column conductor extending in a column direction and disposed adjacent to the first row conductor and adjacent to the second row conductor. The array also includes a dielectric layer covering at least a portion of the column conductor, a fuse link coupled between the dielectric layer on the column conductor and the second row conductor. | 01-12-2012 |
20140050006 | DIODE-LESS ARRAY FOR ONE-TIME PROGRAMMABLE MEMORY - A one-time programmable memory array includes a first row conductor extending in a first row direction and disposed at a first elevation, a second row conductor extending in a second row direction and disposed at a second elevation and a column conductor extending in a column direction and disposed adjacent to the first row conductor and adjacent to the second row conductor. The array also includes a dielectric layer covering at least a portion of the column conductor, a fuse link coupled between the dielectric layer on the column conductor and the second row conductor. | 02-20-2014 |