Waveguide mount for microstrip circuit and material characterization

What is claimed is: 1. A superconducting film device comprising: a superconducting microstrip device including: a silicon substrate disposed on a silicon handling wafer; a microstrip feed line; and a plurality of superconducting microstrip resonators and a half-wavelength resonator, disposed on said silicon substrate and coupled to said microstrip feed line; wherein said silicon substrate is a single-crystal silicon substrate of 50 μm in thickness. 2. The superconducting film device of claim 1 , wherein said plurality of superconducting microstrip resonators are niobium titanium nitride (NbTiN) microstrip resonators, and said NbTiN microstrip resonators are 80, 40, and 20 μm in width, and respectively 550, 534 and 510 μm in length. 3. The superconducting film device of claim 2 , wherein said half-wavelength resonator is a niobium (Nb) half-wavelength resonator, and said Nb resonator is 20 μm in width and 510 μm in length. 4. The superconducting film device of claim 3 , wherein said silicon handling wafer has a thickness of 325 μm, a length of 6 mm, and a width of 1.5 mm. 5. The superconducting film device of claim 4 , wherein said microstrip feedline is a niobium (Nb) microstrip feedline; and wherein said NbTiN microstrip resonators and said Nb resonator, are each disposed 8 μm away from said Nb microstrip feed line. 6. A waveguide-to-microstrip line transition package for superconducting film characterization, comprising: a superconducting microstrip device of claim 1 ; and a fixture in which said microstrip device is disposed; wherein said fixture comprises: a plurality of blocks which form a waveguide housing, and which are used to align and secure said silicon handling wafer of said microstrip device to said fixture; a waveguide septum made from a sheet; and a plurality of direct current (DC) probes disposed adjacent to said waveguide septum, and which contact said microstrip device to provide at least DC bias; and further wherein a thickness of said waveguide is 100 μm, and said waveguide septum is formed from gold-plated beryllium-copper (BeCu). 7. The package of claim 6 , wherein said plurality of blocks is formed from copper, and said fixture further comprises: a photonic choke milled onto a wall of said waveguide housing around and flanking said waveguide septum, and which defines a repeatable minimal-loss interface with high field confinement. 8. The package of claim 6 , further comprising: a spring disposed under said microstrip device, which presses said microstrip device against said waveguide septum. 9. The package of claim 6 , further comprising: a waveguide structure which accommodates two waveguides, each of said waveguides which are disposed in a port of said waveguide structure; wherein each said port transmits and receives millimeter wave power into and out of said microstrip device contained in said fixture. 10. The package of claim 9 , wherein said waveguide structure includes a plurality of stages, including a plurality of ridge-guides which convert said waveguide from a relatively larger width to a relatively smaller width, ending at said microstrip device; and wherein said plurality of ridge-guides are implemented as said waveguide septum in said fixture. 11. The package of claim 10 , wherein said septum is 100 μm in width, and a 26Ω characteristic impedance microstrip line width is 150 μm, allowing placement of said waveguide septum within a +/−25 μm alignment tolerance. 12. The package of claim 11 , wherein a ground plane of said microstrip device is realized from 0.5 μm thick niobium (Nb). 13. The package of claim 6 , wherein transmission of the package, as well as loss, is evaluated in the superconducting film through a quality factor (Q) measurement. 14. The package of claim 9 , wherein said waveguides are formed of at least one of stainless steel or copper. 15. The package of claim 14 , further comprising: a cryogenic test apparatus in which said fixture and said waveguides are disposed, said test apparatus including: a dewar containing liquid helium; a shield which surrounds said microstrip device disposed in said fixture; wherein said microstrip device in said fixture is connected to said liquid helium by a heat strap; a helium gas purge line, which purges helium gas from said fixture; a vacuum window, which seals room temperature ends of said waveguides; wherein said ends of said waveguides are connected to millimeter wave extension modules via 10 dB couplers and 10 dB attenuators; and a heater which prevents cooling of said vacuum window below dew point. 16. The package of claim 15 , wherein said microstrip device is operated between 90 and 100 GHz, is used to measure quality factor and extract complex propagation properties to an accuracy of a few parts per thousand. 17. The package of claim 16 , wherein said fixture is operated with a temperature range of from sub-kelvin to 320 K.