Evaluation of negative bias temperature instability in ultra-thin gate oxide pMOSFETs using a new on-line PDO method

doi:10.1088/1009-1963/15/10/041

Abstract

Abstract A new on-line methodology is used to characterize the negative bias temperature instability (NBTI) without inherent recovery. Saturation drain voltage shift and mobility shift are extracted by I_D-V_D characterizations, which were measured before stress, and after every certain stress phase, using the proportional differential operator (PDO) method. The new on-line methodology avoids the mobility linearity assumption as compared with the previous on-the-fly method. It is found that both reaction--diffusion and charge-injection processes are important in NBTI effect under either DC or AC stress. A similar activation energy, 0.15 eV, occurred in both DC and AC NBTI processes. Also degradation rate factor is independent of temperature below 90℃ and sharply increases above it. The frequency dependence of NBTI degradation shows that NBTI degradation is independent of frequencies. The carrier tunnelling and reaction--diffusion mechanisms exist simultaneously in NBTI degradation of sub-micron pMOSFETs, and the carrier tunnelling dominates the earlier NBTI stage and the reaction--diffusion mechanism follows when the generation rate of traps caused by carrier tunnelling reaches its maximum.

Keywords: negative bias temperature instability proportional differential operator degradation

Received: 27 March 2006
Revised: 02 June 2006
Accepted manuscript online:

PACS:	85.30.Tv	(Field effect devices)
	72.20.Fr	(Low-field transport and mobility; piezoresistance)
	85.30.De	(Semiconductor-device characterization, design, and modeling)

Fund: Project supported by the State Key Development Program for Basic Research of China (Grant No G2000-036503).

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Ji Zhi-Gang (纪志罡), Xu Ming-Zhen (许铭真), Tan Chang-Hua (谭长华) Evaluation of negative bias temperature instability in ultra-thin gate oxide pMOSFETs using a new on-line PDO method 2006 Chinese Physics 15 2431

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Evaluation of negative bias temperature instability in ultra-thin gate oxide pMOSFETs using a new on-line PDO method

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