Measurements of the transmission phase in transport through a quantum dot embedded in an Aharonov-Bohm interferometer show systematic sequences of phase lapses separated by Coulomb peaks. Using a two-level quantum dot as an example we show that this phenomenon can be accounted for by the combined effect of asymmetric dot-lead coupling and interaction-induced "population switching" of the levels, rendering this behavior generic. In addition, we use the notion of spectral shift function to analyze the relationship between transmission phase lapses and the Friedel sum rule.In a series of experiments by the Weizmann group, the transmission phase, Θ tr , characterizing transport through a quantum dot (QD) has been systematically studied 1,2,3 , embedding the QD in an Aharonov-Bohm interferometer 4,5 . Arguably the most intriguing finding of these experiments has been the correlated behavior of Θ tr as function of the leads' chemical potential µ (or the gate voltage): it appears to undergo a lapse (phase lapse, PL), seemingly of −π, between any two consecutive Coulomb peaks. It is clear that this effect cannot be explained within a single-particle framework 6 . Moreover, in spite of a substantial body of theoretical work (see, e.g., Refs. 7,8,9), some of which gained important insight on the underlying physics, no clear cut theoryexperiment connection has been established as yet.In the present article we revisit this problem. We do this by studying a (spinless) two-level QD, attached to two leads. We account for the difference in the couplings of level 1 and level 2 to the leads ("1 − 2 asymmetry") and, for the first time, probe the effect of the (generically expected) asymmetric coupling to the left and the right leads ("L-R asymmetry"). We find unexpectedly that these two asymmetries give rise to a qualitatively new behavior of Θ tr (µ), and render the appearance of PL between consecutive Coulomb peaks generic. This conclusion is in line with recent renormalisation group results for a QD with degenerate levels 10 .Throughout the discussion of transmission PLs in the literature, much attention was paid to the Friedel sum rule, which, in one dimension, relates the transmission phase to the change of carrier population in the system (see, e.g., Refs. 11,12). Since the latter varies monotonously with the chemical potential (or gate voltage), one may perceive a contradiction between this sum rule and the occurrence of PLs. We revisit this issue in Appendix A and show, in particular, that the correct formulation of Friedel sum rule in one dimension allows for transmission phase lapses.The minimal model for studying the phase lapse mechanism includes a two-level QD,Here, the operatorsd i with i = 1, 2 annihilate electrons on the two dot sites (with bare energies E. The QD is coupled to the two leads by the tunnelling termThe operatorsĉ j (with half-integer j) are defined on the tight-binding sites of the left and right lead (cf. Fig. 1). We begin with summarizing the results of Ref.13 (see also Refs. 12,14,15,16) in the cas...
