We consider iron impurities in the noble metals gold and silver and compare experimental data for the resistivity and decoherence rate to numerical renormalization group results. By exploiting non-Abelian symmetries we show improved numerical data for both quantities as compared to previous calculations [Costi et al., Phys. Rev. Lett. 102, 056802 (2009)], using the discarded weight as criterion to reliably judge the quality of convergence of the numerical data. In addition we also carry out finite-temperature calculations for the magnetoresistivity of fully screened Kondo models with S = 1 2 , 1 and 3 2 , and compare the results with available measurements for iron in silver, finding excellent agreement between theory and experiment for the spin-3 2 three-channel Kondo model. This lends additional support to the conclusion of Costi et al. that the latter model provides a good effective description of the Kondo physics of iron impurities in gold and silver. 72.70.+m, 75.20.Hr The magnetic alloys for which the Kondo effect was first observed, in the 1930s, were iron impurities in gold and silver 1,2 . They showed an anomalous rise in the resistivity with decreasing temperature, which Kondo explained in 1964 as being due to an antiferromagnetic exchange coupling between the localized magnetic impurity spins and the spins of the delocalized conduction electrons 3 . For his work, Kondo used a spin-1 2 , one-band model, which undoubtedly captures the essential physics correctly in a qualitative way.However, detailed comparisons between theory and experiment have since shown that this model does not yield a quantitatively correct description of the Kondo physics of dilute Fe impurities in Au or Ag. Such a description must meet the challenge of quantitatively reproducing, using the Kondo temperature T K as only fitting parameter, several independent sets of experimental measurements: the contributions by magnetic impurities (indicated by a subscript m) to the temperatureand field-dependence of the resistivity, ρ m (T, B), and to the temperature-dependence of the decoherence rate, γ m (T ), extracted from weak (anti)localization measurements. The spin-1 2 , 1-band Kondo model does not meet this challenge: when comparing its predictions, obtained by the numerical renormalization group (NRG) 4-6 , to transport measurements on dilute Fe impurities in Ag wires, different Kondo scales were required for fitting the resistivity and decoherence rates 7,8 .In a recent publication (Ref. 9, involving most of the present authors, henceforth referred to as paper I), it was argued that the proper effective low-energy Kondo model for Fe in Au or Ag is, in fact, a fully screened, spin-3 2 three-channel Kondo model. paper I arrived at this conclusion by the following chain of arguments. Previous transport experiments 7,8 had indicated that these sys-tems are described by a fully screened Kondo model 10-14 , i.e. a Kondo model in which the local spin, S, is related to the number of conduction bands, n, by S = n/2. As mentioned above, t...
