Abstract
Vertical stacking of heterogeneous two-dimensional (2D) materials has received considerable attention for nanoelectronic applications. In the semiconductor industry, however, the process of integration for any new material is expensive and complex. Thus, first principles-based models that enable systematic performance evaluation of emerging 2D materials at device and circuit level are in great demand. Here, we propose an ‘atom-to-circuit’ modeling framework for all-2D MISFET (metal–insulator–semiconductor field-effect transistor), which has recently been conceived by vertically stacking semiconducting transition metal dichalcogenide (e.g., MoS2), insulating hexagonal boron nitride and semi-metallic graphene. In a multi-scale modeling approach, we start with the development of a first principles-based atomistic model to study fundamental electronic properties and charge transfer at the atomic level. The energy band-structure obtained is then used to develop a physics-based compact device model to assess transistor characteristics. Finally, the models are implemented in a circuit simulator to facilitate design and simulation of integrated circuits. Since the proposed modeling framework translates atomic level phenomena (e.g., band-gap opening in graphene or introduction of semiconductor doping) to a circuit performance metric (e.g., frequency of a ring oscillator), it may provide solutions for the application and optimization of new materials.
Highlights
Functionality of an electronic device originates from the interfacial properties of its constituent materials
Advancement of nanofabrication technology has opened up the possibility of realizing interfaces at their ‘ultimate-limit’ by vertical stacking[1,2,3] or parallel stitching[4] of 2D materials. Since these new materials inherit diverse electronic and opto-electronic properties, novel device functionalities could be engineered from such atomically thin interfaces.[5]. In such vertically stacked van der Waal’s heterostructures,[6] the individual layers are ‘glued’ together by weak van der Waal’s forces of interaction,[7] whereas the in-plane atoms are strongly bound by covalent or ionic bonds
We propose hierarchical bottom-up modeling methodology for all-2D MISFET that bridges between three levels of abstraction viz. material, device, and circuit
Summary
Functionality of an electronic device originates from the interfacial properties of its constituent materials. To further quantify the charge redistribution, we have calculated the area silicon gate of Si MOSFETs) is expected to play a very crucial role in dictating the MIS capacitor and transistor characteristics Energy (both n band structures of the vdWH comprising and p), indicating unaltered band gaps of of n-type and both graphene p-type MoS2 and MoS2 It shows that graphene is kept pristine, effectively it becomes n or p-type in accordance to the type of doping due to interlayer charge transfer higher the value, more pronounced is the charge redistribution with more chemical interactions occurring at the interface.
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