Title :
Stress management in sub-90-nm transistor architecture
Author :
Arghavani, R. ; Yuan, Z. ; Ingle, N. ; Jung, K.B. ; Seamons, M. ; Venkataraman, S. ; Banthia, V. ; Lilja, K. ; Leon, P. ; Karunasiri, G. ; Yoon, S. ; Mascarenhas, A.
Author_Institution :
Appl. Mater. Inc., Santa Clara, CA, USA
Abstract :
This brief focuses on the physical characteristics of three dielectric films which can induce a significant degree of tensile or compressive stress in the channel of a sub-90-nm node MOS structure. Manufacturable and highly reliable oxide films have demonstrated, based on simulation, the ability to induce greater than 1.5-GPa tensile stress in the Si channel, when used as shallow trench isolation (STI) fill. Low-temperature blanket nitride films with a stress range of 2 GPa compressive to greater than 1.4 GPa tensile were also developed to enhance performance in both PMOS and NMOS devices. Combined with a tensile first interlayer dielectric film, the stress management and optimization of the above films can yield significant performance improvement without additional cost, or integration complexities.
Keywords :
MOS integrated circuits; MOSFET; compressive strength; dielectric thin films; nanoelectronics; silicon; tensile strength; 90 nm; MOS structure; NMOS device; PMOS device; STI; Si; Si channel; compressive stress; dielectric films; film optimization; low-temperature blanket nitride films; oxide films; semiconductor device fabrication; semiconductor films; shallow trench isolation; stress management; sub-90 nm transistor architecture; tensile first interlayer dielectric film; tensile stress; Capacitive sensors; Compressive stress; Dielectric films; Isolation technology; Lattices; MOS devices; Moore´s Law; Semiconductor films; Silicon germanium; Tensile stress; Dielectric films; semiconductor device fabrication; semiconductor films;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2004.835993
