Formation of S0 galaxies through mergers Evolution in the Tully-Fisher relation since z ∼ 1

Context. Lenticular (S0) galaxies are known to derive from spiral galaxies. The fact that S0s nearly obey the Tully-Fisher relation (TFR) at z similar to 0 (as spirals have done in the last similar to 9 Gyr) is considered an argument against their major-merger origin because equal mergers of two disc galaxies produce remnants that are outliers of the TFR. Aims. We explore whether a scenario that combines an origin by mergers at z similar to 1.8-1.5 with a subsequent passive evolution of the resulting S0 remnants since z similar to 0.8-1 is compatible with observational data of S0s in the TFR both at z similar to 0.8 and z similar to 0. Methods. We studied a set of major and minor merger experiments from the GalMer database that generate massive S0 remnants that are dynamically relaxed and have realistic properties. We analysed the location of these remnants in the photometric and stellar TFRs assuming that they correspond to z similar to 0.8 galaxies. We then estimated their evolution in these planes over the last similar to 7 Gyr considering that they have evolved passively in isolation. The results were compared with data of real S0s and spirals at different redshifts. We also tested how the use of V-circ or V-rot,V-max affects the results. Results. Just after similar to 1-2 Gyr of coalescence, major mergers generate S0 remnants that are outliers of the local photometric and stellar TFRs (as already stated in previous studies), in good agreement with observations at z similar to 0.8. After similar to 4-7 Gyr of passive evolution in isolation, the S0 remnants move towards the local TFR, although the initial scatter among them persists. This scatter is sensitive to the indicator used for the rotation velocity: V-circ values yield a lower scatter than when V-rot,V-max values are considered instead. In the planes involving V-rot,V-max, a clear segregation of the S0 remnants in terms of the spin-orbit coupling of the model is observed, in which the remnants of retrograde encounters overlap with local S0s hosting counter-rotating discs. The location of the S0 remnants at z similar to 0 agrees well with the observed distribution of local S0 galaxies in the sigma(0)-M-K, V-circ-sigma(0), and V-rot,V-max-sigma(0) planes. Conclusions. Massive S0 galaxies may have been formed through major mergers that occurred at high redshift and have later evolved towards the local TFR through passive evolution in relative isolation, a mechanism that would also contribute to the scatter observed in this relation.