Reconfigurable radiofrequency electronic functions designed with 3D Smith Charts in Metal-Insulator-Transition Materials
Andrei Muller, Alin Moldoveanu, Victor Asavei, Riyaz Khadar, Esther, Sanabria Codesal, Anna Krammer, Montserrat Fernandez-Bola\~nos, Matteo, Cavalleri, Junrui Zhang, Emanuele Casu, Andreas Schuler, Adrian Mihai Ionescu

TL;DR
This paper introduces 3D Smith charts for analyzing complex RF circuits with Metal-Insulator-Transition materials like VO2, enabling better visualization, modeling, and design of reconfigurable RF components across a broad frequency range.
Contribution
It develops a novel 3D Smith chart framework based on geometric concepts to visualize and model frequency-dependent impedances in MIT materials, addressing theoretical inconsistencies in traditional charts.
Findings
Fabricated VO2-based inductors with record quality factors.
Demonstrated reconfigurable inductors operating from 4 GHz to 10 GHz.
Designed and fabricated frequency-dependent dielectric constant extraction filters.
Abstract
Recently, the field of Metal-Insulator-Transition (MIT) materials has emerged as an unconventional solution for novel energy efficient electronic functions, such as steep slope subthermionic switches, neuromorphic hardware, reconfigurable radiofrequency functions, new types of sensors, teraherz and optoelectronic devices. Designing radiofrequency (RF) electronic circuits with a MIT material like vanadium dioxide, VO2, requires the understanding of its physics and appropriate models and tools, with predictive capability over large range of frequency (1-100GHz). Here, we develop 3D Smith charts for devices and circuits having complex frequency dependences, like the ones resulting by the use of MIT materials. The novel foundation of a 3D Smith chart involves here the geometrical fundamental notions of oriented curvature and variable homothety in order to clarify first theoretical…
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Taxonomy
TopicsTransition Metal Oxide Nanomaterials · Magnetic properties of thin films · Chemical and Physical Properties of Materials
