Title :
Plasma immersion ion implantation as an alternative deep trench buried-plate doping technology
Author :
Lee, Kilho ; Lee, Brian ; Hoepner, J. ; Economikos, Laertis ; Parks, Christopher ; Radens, Carl ; Bernstein, J. ; Kellerman, P.
Author_Institution :
Infineon Technol. Corp., Hopewell Junction, NY, USA
Abstract :
Plasma immersion ion implantation (PIII) has been developed as an alternative deep trench capacitor buried-plate doping technology and compared to a conventional solid-state diffusion technique using arsenosilicate glass (ASG). Novel top-down (or vertical) SIMS measurements demonstrated the conformal doping capability of PIII along the trench sidewall. The doping level by PIII was almost one order of magnitude higher than that by a conventional technique. As a consequence, PIII provided better depletion characteristics than conventional technique. Furthermore, PIII processing did not degrade node-to-buried plate leakage current characteristics. From these results, it was demonstrated that PIII is a promising technology as an alternative deep trench capacitor buried-plate doping technique for future deep trench-based DRAM processing development
Keywords :
DRAM chips; integrated circuit technology; ion implantation; leakage currents; plasma materials processing; secondary ion mass spectra; semiconductor doping; PIII; SIMS; arsenosilicate glass; conformal doping capability; deep trench buried-plate doping technology; deep trench-based DRAM processing development; depletion characteristics; doping level; node-to-buried plate leakage current characteristics; plasma immersion ion implantation; solid-state diffusion technique; trench sidewall; Capacitance; Capacitors; Dielectrics; Electrodes; Plasma immersion ion implantation; Random access memory; Semiconductor device doping; Silicon; Substrates; Voltage;
Conference_Titel :
Ion Implantation Technology, 2000. Conference on
Conference_Location :
Alpbach
Print_ISBN :
0-7803-6462-7
DOI :
10.1109/.2000.924187
