Journal
CHAOS
Volume 32, Issue 3, Pages -Publisher
AIP Publishing
DOI: 10.1063/5.0084395
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Funding
- Powell Endowment Award for Research and Scholarship [25400394]
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This experimental study investigates the nonlinear loss mechanism between traveling localized excitation and the underlying extended normal mode spectrum for a 1D lattice using three types of cyclic, electric, nonlinear transmission lines. It is found that supertransmission can be achieved when the two nonlinear terms are balanced in the capacitive+inductive NLTL configuration.
In this experimental study of the nonlinear loss mechanism between traveling localized excitation and the underlying extended normal mode spectrum for a 1D lattice, three types of cyclic, electric, nonlinear transmission lines (NLTLs) are used. They are nonlinear capacitive, inductive, and capacitive+inductive NLTLs. To maintain a robust, steady-state traveling intrinsic localized mode (ILM), a traveling wave driver is used. The ILM loses energy because of a resonance between it and the extended NLTL modes. A wake field excitation is detected directly from ILM velocity experiments by the decrease in ILM speed and by the observation of the wake. Its properties are quantified via a two-dimensional Fourier map in the frequency-wavenumber domain, determined from the measured spatial-time voltage pattern. Simulations support and extend these experimental findings. We find for the capacitive+inductive NLTL configuration, when the two nonlinear terms are theoretically balanced, the wake excitation is calculated to become very small, giving rise to supertransmission over an extended driving frequency range. Published under an exclusive license by AIP Publishing.
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