High-K gate stack breakdown statistics modeled by correlated interfacial layer and high-k breakdown path

“…Some of these include digital and analog wear-out of the percolation path [8], metal filamentation (Ni, Ta-based gates) [9,10], dielectric breakdown induced epitaxy (DBIE) [11] and migration of contact metal from the source / drain ends into the channel causing a short [12,13]. Although SBD and post-BD are phenomena that have been extensively studied both from a statistical viewpoint [14] - [16] and electrical / physical analysis perspective [17] - [19] for SiO 2 /SiON and HK-IL stacks, the key limitation is that in most cases, the algorithm used to accelerate the breakdown is unable to accurately capture the transient between the percolation event and the post-BD phase, where we observe the physical morphological changes in the dielectric at the BD spot. This is due to poor compliance control.…”

The “buffering” role of high-к in post breakdown degradation immunity of advanced dual layer dielectric gate stacks

“…Some of these include digital and analog wear-out of the percolation path [8], metal filamentation (Ni, Ta-based gates) [9,10], dielectric breakdown induced epitaxy (DBIE) [11] and migration of contact metal from the source / drain ends into the channel causing a short [12,13]. Although SBD and post-BD are phenomena that have been extensively studied both from a statistical viewpoint [14] - [16] and electrical / physical analysis perspective [17] - [19] for SiO 2 /SiON and HK-IL stacks, the key limitation is that in most cases, the algorithm used to accelerate the breakdown is unable to accurately capture the transient between the percolation event and the post-BD phase, where we observe the physical morphological changes in the dielectric at the BD spot. This is due to poor compliance control.…”

The “buffering” role of high-к in post breakdown degradation immunity of advanced dual layer dielectric gate stacks

“…Based on the above results, we provide a phenomenological explanation for the bimodal Weibull distribution that resulting from an area-scaling [27][28]47]. A grain diameter of ~20 nm (Fig.…”

“…Weibull slope [40,42] as shown in Fig. 2 [27] proposed that the T BD of a high-κ gate stack is given by a convolution of the time to break the IL and the time to extend the BD path in the high-κ layer at the same location. The correlated high-κ BD is localized above the IL BD path; its localization does not correspond to the high-κ weakest point, thus it does not follow Poisson area scaling and gives rise to the bimodal characteristic.…”

“…Some research groups [27][28]47] Ribes et al [27] argued that a high-κ BD would occur preferentially above the ILinitiated BD path and therefore its location may not correspond to the high-κ weakest point. Consequently, the failure distribution does not follow Poisson area scaling.…”

“…A grain diameter of ~20 nm (Fig. 6.1) implies that many GBs would exist in the high-κ dielectric of the large area devices (~0.6 m 2 [27]). The fact that BD occurs preferentially at GBs (as evidenced in Fig.…”

Nanoscale characterization of advanced high-?? gate dielectric stacks via scanning tunneling microscopy

Impact of bilayer character on High K gate stack dielectrics breakdown obtained by conductive atomic force microscopy