2019
DOI: 10.1103/physrevapplied.12.014030
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Transmission Lines and Metamaterials Based on Quantum Hall Plasmonics

Abstract: The characteristic impedance of a microwave transmission line is typically constrained to a value Z0 = 50 Ω, in-part because of the low impedance of free space and the limited range of permittivity and permeability realizable with conventional materials. Here we suggest the possibility of constructing high-impedance transmission lines by exploiting the plasmonic response of edge states associated with the quantum Hall effect in gated devices. We analyze various implementations of quantum Hall transmission line… Show more

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Cited by 13 publications
(24 citation statements)
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“…From a microwave engineering perspective, the complicated structure of the fields means that the choice of the reference potential is not unique, and so the definition of the characteristic impedance Z 0 of the device can vary [16]. For example, the characteristic impedance can be defined from the microwave S-parameters [11,15,45] by setting it equal to the values of the impedance of the external circuit that minimizes reflection at the electrodes. Using this approach in capacitively coupled QH devices, one obtains [15]…”
Section: Edge Magnetoplasmonsmentioning
confidence: 99%
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“…From a microwave engineering perspective, the complicated structure of the fields means that the choice of the reference potential is not unique, and so the definition of the characteristic impedance Z 0 of the device can vary [16]. For example, the characteristic impedance can be defined from the microwave S-parameters [11,15,45] by setting it equal to the values of the impedance of the external circuit that minimizes reflection at the electrodes. Using this approach in capacitively coupled QH devices, one obtains [15]…”
Section: Edge Magnetoplasmonsmentioning
confidence: 99%
“…Materials in the QH regime have another interesting property, which was sometimes overlooked, that is they exhibit a large voltage drop between opposite edges when a low current is applied. This high voltage to current ratio is related to the large value of the quantum of resistance, h/e 2 ∼ 25kΩ; for this reason, it was pointed out that the QH effect can be exploited to manufacture low-loss transmission lines and resonators with a high characteristic impedance [15]. The characteristic impedance of these devices was estimated to be proportional to the resisitance quantum, and so orders of magnitude higher than the typical value ∼ 50Ω of microwave circuits [16].…”
Section: Introductionmentioning
confidence: 99%
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