Thanks to the high electron velocities, III–V semiconductors have the potential to meet the challenging ITRS requirements for high performance for sub-22-nm technology nodes and at a supply voltage approaching 0.5 V. This paper presents a comparative simulation study of ultrathin-body InAs, In0.53Ga0.47As, and strained Si MOSFETs, by using a comprehensive semiclassical multisubband Monte Carlo (MSMC) transport model. Our results show that: 1) due to the finite screening length in the source-drain regions, III–V and Si nanoscale MOSFETs with a given gate length (LG) may have a quite different effective channel length (Leff); 2) the difference in Leff provides a useful insight to interpret the performance comparison of III–V and Si MOSFETs; and 3) the engineering of the source-drain regions has a remarkable influence on the overall performance of nanoscale III–V MOSFETs.
Performance Benchmarking and Effective Channel Length for Nanoscale InAs, In0.53Ga0.47As, and sSi n-MOSFETs
LIZZIT, Daniel;ESSENI, David;PALESTRI, Pierpaolo;OSGNACH, Patrik;SELMI, Luca
2014-01-01
Abstract
Thanks to the high electron velocities, III–V semiconductors have the potential to meet the challenging ITRS requirements for high performance for sub-22-nm technology nodes and at a supply voltage approaching 0.5 V. This paper presents a comparative simulation study of ultrathin-body InAs, In0.53Ga0.47As, and strained Si MOSFETs, by using a comprehensive semiclassical multisubband Monte Carlo (MSMC) transport model. Our results show that: 1) due to the finite screening length in the source-drain regions, III–V and Si nanoscale MOSFETs with a given gate length (LG) may have a quite different effective channel length (Leff); 2) the difference in Leff provides a useful insight to interpret the performance comparison of III–V and Si MOSFETs; and 3) the engineering of the source-drain regions has a remarkable influence on the overall performance of nanoscale III–V MOSFETs.File | Dimensione | Formato | |
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