Litcius/Paper detail

Ab initio perspective of ultra-scaled CMOS from 2D-material fundamentals to dynamically doped transistors

Aryan Afzalian

2021npj 2D Materials and Applications70 citationsDOIOpen Access PDF

Abstract

Abstract Using accurate dissipative DFT-NEGF atomistic-simulation techniques within the Wannier-Function formalism, we give a fresh look at the possibility of sub-10-nm scaling for high-performance complementary metal oxide semiconductor (CMOS) applications. We show that a combination of good electrostatic control together with high mobility is paramount to meet the stringent roadmap targets. Such requirements typically play against each other at sub-10-nm gate length for MOS transistors made of conventional semiconductor materials like Si, Ge, or III–V and dimensional scaling is expected to end ~12 nm gate-length (pitch of 40 nm). We demonstrate that using alternative 2D channel materials, such as the less-explored HfS 2 or ZrS 2 , high-drive current down to ~6 nm is, however, achievable. We also propose a dynamically doped field-effect transistor concept, that scales better than its MOSFET counterpart. Used in combination with a high-mobility material such as HfS 2 , it allows for keeping the stringent high-performance CMOS on current and competitive energy-delay performance, when scaling down to virtually 0 nm gate length using a single-gate architecture and an ultra-compact design (pitch of 22 nm). The dynamically doped field-effect transistor further addresses the grand-challenge of doping in ultra-scaled devices and 2D materials in particular.

Topics & Concepts

CMOSTransistorMOSFETDopingScalingMaterials scienceOptoelectronicsField-effect transistorNanotechnologyPhysicsVoltageQuantum mechanicsGeometryMathematicsFerroelectric and Negative Capacitance Devices2D Materials and ApplicationsAdvancements in Semiconductor Devices and Circuit Design