Claims
- 1. A smart card comprising:
a processor; and a memory, said memory comprising:
(a) a MOS field effect transistor having a gate, a gate dielectric underlying the gate, and first and second doped semiconductor regions underlying both the gate dielectric and the gate in a spaced apart relationship to define a channel region therebetween; (b) a MOS data storage element having a conductive structure, an ultra-thin dielectric underlying the conductive structure, and a first doped semiconductor region underlying both the ultra-thin dielectric and the conductive structure, the first doped semiconductor region of the MOS data storage element being coupled to the first doped semiconductor region of the MOS field effect transistor; (c) a select line segment coupled to the gate of the MOS field effect transistor; a first access line segment coupled to the second doped semiconductor region of the MOS field effect transistor; and (d) a second access line segment coupled to the conductive structure of the MOS data storage element.
- 2. The smart card of claim 1 wherein each of the MOS data storage elements comprises an inversion-enabled region underlying both the ultra-thin dielectric and the conductive structure and adjacent to the first doped region of the MOS data storage element.
- 3. The smart card of claim 1 wherein each of the MOS data storage elements comprises a second doped region underlying both the ultra-thin dielectric and the conductive structure and integrated with the first doped region of the MOS data storage element.
- 4. The smart card of claim 1 wherein the gate dielectric of the MOS field effect transistors and the ultra-thin dielectric of the MOS data storage elements are formed from a common layer of ultra-thin gate oxide.
- 5. The smart card of claim 1 wherein the gate dielectric of the MOS field effect transistors is thicker than the ultra-thin dielectric of the MOS data storage elements.
- 6. A smart card comprising:
a processor; and a memory array having select and access lines, said memory array having a plurality of programmable read only memory cells, the memory cells comprising a select transistor coupled in series with a data storage element between two access lines, the select transistor further having a gate coupled to one of the select lines, and the data storage element comprising an ultra-thin dielectric for physical storage of data.
- 7. The smart card of claim 6 wherein the data storage element is a MOS half-transistor.
- 8. The smart card of claim 6 wherein the data storage element is a MOS capacitor.
- 9. A method of programming a smart card that includes a programmable read only memory array comprising a plurality of row lines, a plurality of column lines, at least one source line, and a plurality of memory cells at respective crosspoints of the row lines and column lines, each of the memory cells comprising a MOS field effect transistor coupled in series with a MOS data storage element between one of the column lines and one of the at least one source line, the MOS transistor further having a gate coupled to one of the row lines and the MOS data storage element comprising an ultra-thin dielectric for physical storage of data, the method comprising:
applying a first voltage to a selected one of the row lines for turning on each of MOS field effect transistor having the gate thereof coupled to the selected row line; applying a second voltage to a selected one of the column lines; and applying a third voltage to the at least one source line; wherein the second voltage and the third voltage cause a potential difference across the ultra-thin dielectric of the memory cell coupled to the selected row line and the selected column line that is sufficient to break down the ultra-thin dielectric thereof.
- 10. The method of claim 9 wherein the breakdown of the ultra-thin dielectric is a hard breakdown.
- 11. The method of claim 9 wherein the breakdown of the ultra-thin dielectric is a soft breakdown.
- 12. The method of claim 9 wherein the first voltage is about 2.5 volts, the second voltage is about 7 volts, and the third voltage is about 0 volts.
- 13. The method of claim 8 wherein the first voltage is about 7 volts, the second voltage is about 7 volts, and the third voltage is about 0 volts.
- 14. The method of claim 8 wherein the first voltage is about 2.5 volts, the second voltage is about 2.5 volts, and the third voltage is about −4.5 volts.
- 15. A smart card having a programmable read only memory array comprising a plurality of row lines, a plurality of column lines, at least one shared line, and a plurality of memory cells at respective crosspoints of the row lines and column lines in the memory, each of the memory cells comprising a select transistor coupled in series with a data storage element between one of the column lines and one of the at least one shared line, the select transistor further having a gate coupled to one of the row lines and the data storage element comprising an ultra-thin dielectric for physical storage of data.
- 20. The smart card of claim 19 wherein the data storage element is a MOS half-transistor.
- 21. The smart card of claim 19 wherein the data storage element is a MOS capacitor.
- 22. A integrated circuit memory card having memory comprised of non-volatile memory cells, each memory cell comprising a select transistor coupled in series with a data storage element, the data storage element comprising a conductive structure, an ultra-thin dielectric underlying said conductive for physical storage of data, and a first doped semiconductor region underlying both the ultra-thin dielectric and the conductive structure, said select transistor having a gate that is controllable to address said memory cell.
- 23. The memory card of claim 22 wherein the data storage element is a MOS half-transistor.
- 24. The memory card of claim 22 wherein the data storage element is a MOS capacitor.
- 25. The memory card of claim 22 wherein said ultra-thin dielectric is a gate oxide.
- 26. The memory card of claim 25 wherein said gate oxide is less than 50 angstroms thick.
- 27. The memory card of claim 25 wherein said memory cells are programmed by breaking down said gate oxide by applying a voltage between said conductive structure and said first doped semiconductor region.
- 28. The memory card of claim 27 wherein said memory cells are read by sensing a current through said data storage element during application of a voltage between said conductive structure and said first doped semiconductor region.
- 29. The memory card of claim 22 further including an input/output means for accessing said memory.
- 30. A smart card comprising:
a memory, said memory comprising:
(a) a MOS field effect transistor having a gate, a gate dielectric underlying the gate, and first and second doped semiconductor regions underlying both the gate dielectric and the gate in a spaced apart relationship to define a channel region therebetween; (b) a MOS data storage element having a conductive structure, an ultra-thin dielectric underlying the conductive structure, and a first doped semiconductor region underlying both the ultra-thin dielectric and the conductive structure, the first doped semiconductor region of the MOS data storage element being coupled to the first doped semiconductor region of the MOS field effect transistor; (c) a select line segment coupled to the gate of the MOS field effect transistor; a first access line segment coupled to the second doped semiconductor region of the MOS field effect transistor; and
(d) a second access line segment coupled to the conductive structure of the MOS data storage element.
- 31. The smart card of claim 30 wherein each of the MOS data storage elements comprises an inversion-enabled region underlying both the ultra-thin dielectric and the conductive structure and adjacent to the first doped region of the MOS data storage element.
- 32. The smart card of claim 30 wherein each of the MOS data storage elements comprises a second doped region underlying both the ultra-thin dielectric and the conductive structure and integrated with the first doped region of the MOS data storage element.
- 33. The smart card of claim 30 wherein the gate dielectric of the MOS field effect transistors and the ultra-thin dielectric of the MOS data storage elements are formed from a common layer of ultra-thin gate oxide.
- 34. The smart card of claim 30 wherein the gate dielectric of the MOS field effect transistors is thicker than the ultra-thin dielectric of the MOS data storage elements.
RELATED APPLICATION
[0001] The present application hereby claims priority under 35 U.S.C. 120 from U.S. patent application Ser. No. 09/995,641 filed Sep. 18, 2001 entitled “SEMICONDUCTOR MEMORY CELL AND MEMORY ARRAY USING A BREAKDOWN PHENOMENA IN AN ULTRA-THIN DIELECTRIC”.