Title :
Improving the Endurance of Nonvolatile Flash Memory Using Micro-Grain Poly-Silicon Floating Gate
Author :
Luoh, Tuung ; Yang, Ling-Wu ; Yang, Tahone ; Chen, Kuang-Chao ; Lu, Chih-Yuan
Author_Institution :
Technol. Dev. Center, Macronix Int. Semicond. Co., Ltd., Hsinchu, Taiwan
Abstract :
This paper applied a grain-refinement technique to develop an alternative poly-silicon floating gate. Micro-grain poly-silicon grains were refined by using a single-wafer LPCVD processor and adding hydrogen. The SIMS analysis of micro-grain poly-silicon films revealed that hydrogen contributed to poly-silicon formation but was not incorporated into the poly-silicon films. The grain size and dopant concentration of poly-silicon affected oxide integrity. The grain size of micro-grain poly-silicon was well controlled under 15 nm by annealing with 950°C /30s N2. A 100 k-cycle erase-program endurance test of a single-wafer LPCVD processor confirmed that the micro-grain floating gate poly-silicon with hydrogen had better endurance compared to conventional furnace poly-silicon.
Keywords :
annealing; chemical vapour deposition; elemental semiconductors; flash memories; grain refinement; grain size; random-access storage; semiconductor doping; silicon; SIMS analysis; annealing; dopant concentration; erase-program endurance test; furnace polysilicon; grain size; grain-refinement technique; hydrogen; micrograin polysilicon films; micrograin polysilicon floating gate; nonvolatile flash memory; oxide integrity; polysilicon formation; single-wafer LPCVD processor; Endurance; fast erase; floating gate; micro-grain poly-silicon; thermal stability;
Journal_Title :
Semiconductor Manufacturing, IEEE Transactions on
DOI :
10.1109/TSM.2010.2048964
