Engenharia Elétrica
URI permanente desta comunidadehttps://repositorio.fei.edu.br/handle/FEI/21
Navegar
2 resultados
Resultados da Pesquisa
- Uniaxial stress efficiency for different fin dimensions of triple-gate SOI nMOSFETs(2011-10-06) BÜHLER, Rudolf Theoderich; AGOPIAN, P. G. D.; Renato Giacomini; SIMOEN, E.; CLAEYS, C.; MARTINO, J. A.The stress profiles extracted showed that the variation in the silicon fin dimensions influence the stress levels and distributions along the silicon fin. From the analog performance view, these variations in the stress have influence on some electric parameters. The reduction of the total fin length showed no significant change in the parameters, although a reduction in the stress level was noticed, leading to the conclusion that the shift in the stress level is too small to cause a pronounced impact on the parameters. On the other hand, the reduction of the silicon fin height showed more interesting results. Despite that the standard device with smaller fin height presented a lower intrinsic voltage gain performance when compared to the reference device, when implementing strain it supersedes the reference device and presented an enhancement in the intrinsic voltage gain over the standard one up to 8 %, larger than the 5.1 % obtained for the reference device. © 2011 IEEE.
- Biaxial + uniaxial stress effectiveness in tri-gate SOI nMOSFETs with variable fin dimensions(2012-10-04) BÜHLER, Rudolf Theoderich; Agopian P.G.D.; Simoen E.; Claeys C.; Martino J.A.MuGFET devices show good gate-to-channel control, reducing short channel effects and increased current drive [1] and their performance can be improved through implementation of mechanical stress in the silicon fin. In th is wor k we study t he stress distr ibution and transconductance behavior in unstrained and biaxially + uniaxially strained tri-gate SOI nMOSFETs with different fin dimensions through electrical characterization of experimental devices and 3D process and device numerical simulation. Experimental results of standard and strained devices were used to validate the simulations. The bi+uni stress technique delivered enhanced maximum transconductance. © 2012 IEEE.