Watching a Superconducting Coplanar Waveguide Heat Up with a Single Color Center

Abstract

Single color centers in diamond offer a local probe of their cryogenic environment, providing a direct way to quantify heating in spin-control hardware. Here, we establish a single spectrally stable tin-vacancy (SnV) center as an on-chip thermometer for a diamond membrane and use it to characterize microwave- and radio-frequency-induced heating in a superconducting coplanar waveguide patterned on the same chip. We first calibrate the temperature dependence of the optical C-transition frequency and linewidth from 20\,K down to the few-kelvin regime. At lower temperatures, where the optical response becomes weakly temperature dependent, we use the spin-lattice relaxation time T1 as a complementary thermometer and tune its sensitivity with the transverse magnetic-field component. Applying this local thermometer to a niobium coplanar waveguide, we observe magnetic-field-dependent superconducting breakdown under GHz drive, accompanied by abrupt heating of the diamond. In contrast, at 20\,MHz and 400\,mT, relevant for nuclear-spin control, we detect no measurable heating up to the breakdown threshold of 9.4\,dBm, corresponding to Bac1.2\,mT. These results define a safe operating window for superconducting microwave and RF control structures in diamond-based quantum nodes.