Influence of Size and Interface Effects of Silicon Nanowire and Nanosheet for Ultra-Scaled Next Generation Transistors
Abstract
In this work, we investigate the trade-off between scalability and reliability for next generation logic-transistors i.e. Gate-All-Around (GAA)-FET, Multi-BridgeChannel (MBC)-FET. First, we analyze the electronic properties (i.e. bandgap and quantum conductance) of ultra-thin silicon (Si) channel i.e. nano-wire and nano-sheet based on first principle simulation. In addition, we study the influence of interface states (or dangling bonds) at Si-SiO2 interface. Second, we investigate the impact of bandgap change and interface states on GAA-FETs and MBC-FETs characteristics by employing Non-equilibrium Green’s Function based device simulation. In addition to that we calculate the activation energy of Si-H bond dissociation at Si-SiO2 interface for different Si nano-wire/sheet thickness and different oxide electric-field. Utilizing these thickness dependent activation energies for corresponding oxide electric-field, in conjunction with reaction-diffusion model, we compute the characteristics shift and analyze the negative bias temperature instability in GAA-FET and MBC-FET. Based on our analysis, we estimate the operational voltage of these transistors for a life-time of 10 years and the ON current of the device at iso-OFF-current condition. For example, for channel length of 5 nm and thickness <5 nm the safe operating voltage needs to be><0.55V. Furthermore, our analysis suggests that the benefit of Si thickness scaling can potentially be suppressed for obtaining a desired life-time of GAA-FET and MBC-FET.
Degree
M.Sc.
Advisors
Schubert, Purdue University.
Subject Area
Energy|Design|Atomic physics|Electromagnetics|Industrial engineering|Mathematics|Nanotechnology|Physics
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