Resolving the Corbino Shockley-Ramo Paradox for Hydrodynamic Current Noise

Johnson noise thermometry enables direct measurement of the electron temperature, a valuable probe of many-body systems. Practical use of this technique calls for non-equilibrium generalizations of the Johnson-Nyquist theorem. For a hydrodynamic Corbino device, however, a naive use of the Shockley-Ramo theorem alongside the "Corbino paradox'' leads to yet another paradox: bulk velocity fluctuations cannot be measured by the contacts. In this work, we resolve the unphysical "Corbino Shockley-Ramo paradox'' by correctly formulating the hydrodynamic Shockley-Ramo problem. This allows us to properly formulate the problem of current noise in an hydrodynamic multi-terminal device of arbitrary geometry, as well as validate a previously unjustified assumption for rectangular geometry results. As an example, we compute the Johnson noise in a hydrodynamic Corbino device, where we find a suppression of Johnson noise with magnetic field. This unusual characteristic serves as a strong signature of viscous hydrodynamic behavior.