Integrated Sliding-Short/Probe Tuner with Doorknob Transition for High-Q Cavities

Abstract

We present an integrated three-knob tuner that internalizes impedance matching inside the launch adapter of a waveguide-fed, high-Q cavity. The tuner combines a waveguide sliding short, a doorknob transition, and a micrometer-driven adjustable coaxial probe. A transmission-line/ABCD model is derived that maps the three mechanical degrees of freedom to the electrical objectives → 0, β, and Q L, explicitly including the fused-silica feedthrough capacitance. The model yields closed-form matching conditions and predicts the critical-coupling set. Full-wave FEM simulations and bench measurements validate the approach: with h ≈ 0.55~mm and backshort distance ≈ 0.80~mm, the return loss reaches |S11| ≈ -30~dB near 17.8--18.1~GHz while sustaining peak electric fields of 1.8 × 105~V/m at the nozzle (normalized to 1~W). The measured through loss of the launch assembly is |S21| ≈ 0.7--0.8~dB at resonance. A parametric study shows that backshort lengths L bs ≥ 0.5 λ g excite a parasitic stub resonance, introducing a second S11 minimum and localizing energy behind the doorknob; keeping L bs ≤ 0.4 λg avoids this. In helium plasma discharges at P in = 10~W, in-situ retuning of the short and probe maintained a favorable match as the plasma impedance evolved, increasing absorbed power from 43\% to 76\% while increasing helium propellant flow rate from 25 to 351~sccm. The compact tuner eliminates external stub boxes and generalizes to other waveguide-coupled resonators and plasma sources.

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