| Article ID | Journal | Published Year | Pages | File Type |
|---|---|---|---|---|
| 753299 | Solid-State Electronics | 2009 | 7 Pages |
The difficult scaling of bulk Dynamic Random Access Memories (DRAMs) has led to various concepts of capacitor-less single-transistor (1T) architectures based on SOI transistor floating-body effects. Amongst them, the Meta-Stable Dip RAM (MSDRAM), which is a double-gate Fully Depleted SOI transistor, exhibits attractive performances. The Meta-Stable Dip effect results from the reduced junction leakage current and the long carrier generation lifetime in thin silicon film transistors. In this study, various devices with different gate lengths, widths and silicon film thicknesses have been systematically explored, revealing the impact of transistor dimensions on the MSD effect. These experimental results are discussed and validated by two-dimensional numerical simulations. It is found that MSD is maintained for small dimensions even in standard SOI MOSFETs, although specific optimizations are expected to enhance MSDRAM performances.
