Title :
Reduction of Bipolar Disturb of Floating-Body Cell (FBC) by Silicide and Thin Silicon Film Formed at Source and Drain Regions
Author :
Hamamoto, Takeshi ; Fukuzumi, Yoshiaki ; Higashi, Tomoki ; Nakajima, Hiroomi ; Minami, Yoshihiro ; Shino, Tomoaki ; Ohsawa, Takashi ; Nitayama, Akihiro
Author_Institution :
Device Process Dev. Center, Toshiba Corp., Yokohama, Japan
Abstract :
The cell-to-cell leakage caused by bipolar disturb of the floating-body cell (FBC) has been investigated. In the case of FBC without silicide at the source and drain regions, the change of data “0” to data “1” has been observed in the writing operation to the adjacent cell. However, this leakage can be reduced when the silicide is formed on the thin silicon film at the source and drain regions. It has been clarified that the diffusion of holes inside the n+ region is restricted by the capture of holes at the silicide/silicon interface when silicon thickness reduces. Based on these experimental results, 6F2 layout of FBC can be realized with the conventional logic device process platform.
Keywords :
DRAM chips; MOSFET; elemental semiconductors; logic circuits; silicon; silicon compounds; silicon-on-insulator; thin films; DRAM chips; Si; SiO2; bipolar disturb reduction; cell-to-cell leakage; dynamic random-access memory; floating-body cell; logic device process platform; metal-oxide-semiconductor field-effect transistors; silicide; silicon interface; silicon-on-insulator technology; thin silicon film; Capacitors; FETs; Hot carriers; Logic devices; MOSFETs; Random access memory; Semiconductor films; Silicides; Silicon on insulator technology; Writing; Dynamic random-access memory (DRAM) chips; hot carriers; metal–oxide–semiconductor field-effect transistors (MOSFETs); silicon-on-insulator technology;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2010.2050550
