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Left-handed transmission lines at millimetre and sub-millimetre wavelengths

Left-handed transmission lines at millimetre and sub-millimetre wavelengths

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Published

Co-planar strip (CPS) transmission lines, aimed at operating up to sub-millimetre wavelengths, were periodically loaded by lumped capacitances and inductances in series and shunt configuration, respectively. Under this condition, propagation on the line is backward with group and phase velocities of opposite signs. The transmission lines were fabricated onto a quartz substrate by e-beam patterning and thin film deposition, silicon nitride and gold layers, on a deep sub-micron scale (∼200 nm). A direct evidence of left-handedness between 160 and 380 GHz was achieved via the tracking of phase advance in a differential phase experiment using electro-optic sampling. The comparison between modelling results by electromagnetic full wave circuit analysis and experiment was performed in the time and frequency domains. It shows a good agreement in the dispersion characteristics and ultra-fast variations in the transmitted signals. At last, we took benefit of a lumped element fitting approach in order to discuss of the frequency capability of this non-resonant approach.

Inspec keywords: strip lines; coplanar transmission lines; metamaterials

Other keywords: left-handed transmission lines; millimetre wavelengths; co-planar strip transmission lines; quartz substrate; time domains; 160 to 380 GHz; lumped element fitting approach; differential phase experiment; electromagnetic full wave circuit analysis; nonresonant approach; sub-millimetre wavelengths; phase advance; frequency capability; frequency domains

Subjects: Microwave materials and structures; Waveguides and microwave transmission lines

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