Abstract

In this work, we study the current-phase relation ($\mathrm{C}\mathrm{\ensuremath{\Phi}}\mathrm{R}$) of lithographically fabricated molybdenum germanium (${\mathrm{Mo}}_{79}{\mathrm{Ge}}_{21}$) nanobridges that is intimately linked with the nanobridge's kinetic inductance. We do this by imbedding the nanobridges in a superconducting quantum interference device (SQUID). We observe that, for temperatures far below ${T}_{c}$, the $\mathrm{C}\mathrm{\ensuremath{\Phi}}\mathrm{R}$ is linear, as long as the condensate is not weakened by the presence of a supercurrent. We demonstrate lithographic control over the nanobridge kinetic inductance, which scales with the nanobridge aspect ratio. This allows the ${I}_{c}(B)$ characteristic of the SQUID to be tuned. The SQUID properties that can be controlled in this way include the SQUID's sensitivity and the positions of the critical-current maxima. These observations can be of use for the design and operation of future superconducting devices, such as magnetic memories or flux qubits.