Miguel Saavedra-Melo, Nelson Castro, Robert Marosi, Eva Rajo-Iglesias, Filippo Capolino
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Wideband Glide-Symmetric Double-Corrugated Gap-Waveguide Traveling-Wave Tube for Millimeter Waves
We explore the use of glide symmetry (GS) and electromagnetic bandgap (EBG)
technology in a glide-symmetric double corrugated gap waveguide (GSDC-GW) slow
wave structure (SWS) for traveling wave tube (TWT) applications. Notably, this
GS structure provides the advantage of wide-band operation and the EBG
eliminates the need for a conductive connection between the top and bottom
waveguide plates. The TWT performance is evaluated via particle-in-cell
simulations that reveal a 3-dB bandwidth of approximately 12 GHz spanning from
54.5 GHz to 66.3 GHz, accompanied by a maximum gain of 23 dB. Because of GS,
the backward wave in the first spatial harmonic is not longitudinally
polarized, leading to a low risk of backward wave oscillations in the TWT. This
work places the GSDC-EBG structure within the arena of potential SWS topologies
for TWTs operating under similar conditions.
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