Hot carrier degradation modeling of short-channel n-FinFETs

Figure 1(a) shows the degradation of the transfer characteristics of a typical FinFET with W<sub>fin</sub> = 10 nm, measured at V<sub>d</sub> = 0.03 V after HC stress at V<sub>stress</sub> = 1.8 V for different stress times. The degradation of the device parameters V<sub>t</sub>, η and on-state drain current is clearly observed. The positive V<sub>t</sub> shift indicates the built-up of a negative charge in the gate dielectric. The negative charge can result either from electron trapping in the gate dielectric or from generation of acceptor-type interface traps. Figure 1(b) shows the transconductance g<sub>m</sub> degradation during HC stress. Degradation of the maximum g<sub>m</sub> is observed attributed to the interface degradation, with a simultaneous parallel g<sub>m</sub> shift due to charge injection into the gate dielectric bulk defects [4]. Using the relation SS=(kT/q).qD<sub>it</sub>/C<sub>ox</sub> for the subthreshold slope SS, where C<sub>ox</sub> is the gate oxide capacitance and kT is the thermal energy, from figure 1(a) the extracted interface trap density D<sub>it</sub> changes from 4×10<sup>12</sup> to 5.5×10<sup>12</sup>cm<sup>-2</sup>eV<sup>-1</sup>.

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