Physical Review Research (Jun 2021)

Nonlinearity and wide-band parametric amplification in a (Nb,Ti)N microstrip transmission line

  • S. Shu,
  • N. Klimovich,
  • B. H. Eom,
  • A. D. Beyer,
  • R. Basu Thakur,
  • H. G. Leduc,
  • P. K. Day

DOI
https://doi.org/10.1103/PhysRevResearch.3.023184
Journal volume & issue
Vol. 3, no. 2
p. 023184

Abstract

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The nonlinear response associated with the current dependence of the superconducting kinetic inductance was studied in capacitively shunted NbTiN microstrip transmission lines. It was found that the inductance per unit length of one microstrip line could be changed by up to 20% by applying a dc current, corresponding to a single-pass time delay of 0.7 ns. To investigate nonlinear dissipation, Bragg reflectors were placed on either end of a section of this type of transmission line, creating resonances over a range of frequencies. From the change in the resonance linewidth and amplitude with dc current, the ratio of the reactive to the dissipative response of the line was found to be 788. The low dissipation makes these transmission lines suitable for a number of applications that are microwave- and millimeter-wave band analogs of nonlinear optical processes. As an example, by applying a millimeter-wave pump tone, very-wide-band parametric amplification was observed between about 3 and 34 GHz. Use as a current variable delay line for an on-chip millimeter-wave Fourier transform spectrometer is also considered.