Title :
Retention Tail Improvement for Gbit DRAMs through Trap Passivation confirmed by Activation Energy Analysis
Author :
Weber, A. ; Birner, A. ; Krautschneider, W.
Author_Institution :
Qimonda Dresden GmbH & Co. OHG
Abstract :
A very efficient method to reduce gate induced drain leakage (GIDL) as the dominant leakage path in the tail part of DRAM data retention time distribution is presented. Different to other reports, GIDL is addressed by trap passivation instead of lowering of electric fields. Stable passivation of traps is achieved by implantation of fluorine into S/D regions of 512Mbit and 1Gbit DRAMs in 110 nm technology. It was found that the position of the F-implant within the process flow plays a key role to enable trap reduction and retention tail improvement. Systematic implant experiments were carried out resulting in a fail count reduction of up to 40 %. Detailed activation energy analysis on individual memory cells confirms the validity of the retention tail model and the selective reduction of GIDL traps by fluorine implantation
Keywords :
DRAM chips; electron traps; ion implantation; leakage currents; nanotechnology; passivation; 110 nm; 1E9 bit; 512E9 bit; DRAM; GIDL traps; activation energy analysis; fluorine implantation; gate induced drain leakage; nanotechnology; retention tail improvement; trap passivation; Energy measurement; Implants; Leakage current; Passivation; Probability distribution; Production; Random access memory; Tail; Temperature sensors; Tunneling; DRAM; activation energy; fluorine; retention;
Conference_Titel :
Solid-State Device Research Conference, 2006. ESSDERC 2006. Proceeding of the 36th European
Conference_Location :
Montreux
Print_ISBN :
1-4244-0301-4
DOI :
10.1109/ESSDER.2006.307685
