Title :
Flicker noise in nanoscale pMOSFETs with mobility enhancement engineering and dynamic body biases
Author :
Yeh, Kuo-Liang ; Ku, Chih-You ; Hong, Wei-Lun ; Guo, Jyh-Chyurn
Author_Institution :
Inst. of Electron. Eng., Nat. Chiao Tung Univ., Hsinchu, Taiwan
Abstract :
The uni-axial compressive strain from e-SiGe S/D combined with dynamic body biases effect on flicker noise of pMOSFETs is presented in this paper. This compressive strain contributes higher mobility but the worse flicker noise in terms of higher SID/ID 2 becomes a potential killer to RF/analog circuits. Forward body biases (FBB) can reduce the flicker noise but the degraded body bias effect in strained pMOSFETs makes it not as efficient as the standard ones without strain. Hooge´s mobility fluctuation model is adopted to explain the uni-axial strain and dynamic body biases effect on flicker noise. The increase of Hooge parameter alphaH is identified the key factor responsible the degraded flicker noise in strained pMOSFETs.
Keywords :
Ge-Si alloys; MOSFET; analogue integrated circuits; carrier mobility; flicker noise; nanoelectronics; radiofrequency integrated circuits; semiconductor device models; semiconductor device noise; semiconductor device reliability; semiconductor device testing; semiconductor materials; stress analysis; Hooge parameter; Hooge´s mobility fluctuation model; RF/analog circuits; SiGe; compressive strain; dynamic body biases effect; mobility enhancement engineering; nanoscale pMOSFET flicker noise; strained pMOSFETs; uni-axial compressive strain; uni-axial strain; 1f noise; Analog circuits; CMOS technology; Capacitive sensors; Cutoff frequency; Degradation; Germanium silicon alloys; MOSFETs; Radio frequency; Silicon germanium; Flicker noise; body bias; mobility; pMOSFET; strain;
Conference_Titel :
Radio Frequency Integrated Circuits Symposium, 2009. RFIC 2009. IEEE
Conference_Location :
Boston, MA
Print_ISBN :
978-1-4244-3377-3
Electronic_ISBN :
1529-2517
DOI :
10.1109/RFIC.2009.5135555
