Dispersion diagrams of linear slow-wave structures. Identification of electromagnetic waves, all electromagnetic waves: forward-traveling, backward-traveling and standing electromagnetic waves

Abstract

The analytically calculated dispersion diagram of an overmoded 9-period V-band slow-wave structure (SWS) designed to operate in a high-order transverse-magnetic TM₀₃ waveguide mode of a backward-traveling electromagnetic wave [Ye et al., Phys. Plasmas, 22, 063104 (2015)] is re-examined using the two-dimensional (2D) Poisson SuperFish code allowing to precisely calculate spatial patterns of electric field vectors, wavenumbers and characteristic frequencies of all azimuthally-symmetric TM_0nl cavity modes that exist in a closed SWS, where n and l are the radial and axial indices of TM_0nl cavity modes, respectively [Main et al., IEEE Trans. Plasma Sci., Vol. 22, No. 5, Oct. 1994, p. 566]. It is shown that the analytically calculated higher-order TM_0n waveguide modes of the open SWS are actually not pure TM_0n modes, but fascinating combinations of selected portions of the modes with selected portions of all possible lower-order TM_0(n-j) waveguide modes, where j=1 … (n-1). An analytically calculated TM₀₃ waveguide mode, therefore, turns out to be in fact a combination of three different TM_0n waveguide modes sequentially identified by numerically calculated TM_0nl cavity modes: (i) TM_03l mode with l=0 … 4, (ii) TM_01l mode with l=13 … 11, and (iii) TM_02l mode with l=8 … 9.

Disclosure statement

No potential conflict of interest was reported by the author(s).

Notes

1 The analogous procedure, which does not keep an original picture, is found in Windows 10’s Paint as an “Home/Rotate/Flip horizontal” command.

Additional information

Funding

The work at the University of New Mexico is supported by Defense Advanced Research Projects Agency: [Grant Number N66001-16-1-4042].