Broken unitarity and phase measurements in Aharonov-Bohm interferometers

Aharonov-Bohm mesoscopic solid-state interferometers yield a conductance which contains a term $\cos(\phi+\beta)$, where $\phi$ relates to the magnetic flux. Experiments with a quantum dot on one of the interfering paths aim to relate $\beta$ to the dot's intrinsic Friedel transmission phase, $\alpha_1$. For closed systems, which conserve the electron current (unitarity), the Onsager relation requires that $\beta=0$. For open systems, we show that $\beta$ depends in general on the details of the broken unitarity. Although it gives information on the resonances of the dot, $\beta$ is generally not equal to $\alpha_1$. A direct relation between $\beta$ and $\alpha_1$ requires specific ways of opening the system, which are discussed.