A capacitorless double gate DRAM technology for sub-100-nm embedded and stand-alone memory applications

Author

Kuo, Charles ; King, Tsu-Jae ; Hu, Chenming

Author_Institution

Intel Corp., Santa Clara, CA, USA

Volume

50

Issue

12

fYear

2003

Firstpage

2408

Lastpage

2416

Abstract

A capacitorless, asymmetric double gate DRAM (DG-DRAM) technology is presented. Its double gate, thin body structure reduces dopant fluctuation effects, off-state leakage, and disturb problems. The cell´s large body coefficient amplifies small gains of body potential into increased drain current. Experimental measurements of DG-DRAM were made using recessed channel SOI n-MOSFETs. No significant degradation in programming, retention, and read behavior was observed after 10¹¹ cycles. Cell geometry, operating voltages, and material quality should be considered for DG-DRAM in embedded and stand-alone applications. The feasibility of DG-DRAM in future high density CMOS memories depends on issues such as manufacturability, soft error reliability, and tail bit distribution.

Keywords

CMOS memory circuits; DRAM chips; leakage currents; asymmetric double gate DRAM; capacitorless double gate DRAM technology; dopant fluctuation effects; embedded memory applications; floating body DRAM; high density CMOS memories; large body coefficient; minimum storage capacitance; off-state leakage; recessed channel SOI MOSFET; scaled CMOS; simulation parameters; standalone memory applications; thin body structure; Capacitors; Computer aided manufacturing; Doping profiles; Fluctuations; MOSFETs; Probability distribution; Random access memory; Semiconductor device doping; Threshold voltage; Tunneling;

fLanguage

English

Journal_Title

Electron Devices, IEEE Transactions on

Publisher

ieee

ISSN

0018-9383

Type

jour

DOI

10.1109/TED.2003.819257

Filename

1255603