In a ferromagnet, an applied electric field E invariably produces an anomalous Hall current JH that flows perpendicular to the plane defined by E and M (the magnetization). For decades, the question whether JH is dissipationless (independent of the scattering rate), has been keenly debated without experimental resolution. In the ferromagnetic spinel CuCr2Se4−xBrx, the resistivity ρ (at low temperature) may be increased 1000 fold by varying x(Br), without degrading the M. We show that JH /E (normalized per carrier, at 5 K) remains unchanged throughout. In addition to resolving the controversy experimentally, our finding has strong bearing on the generation and study of spin-Hall currents in bulk samples.A major unsettled question in the study of electron transport in a ferromagnet is whether the anomalous Hall current is dissipationless. In non-magnetic metals, the familiar Hall current arises when electrons moving in crossed electric (E) and magnetic (H) fields are deflected by the Lorentz force. However, in a ferromagnet subject to E alone, a large, spontaneous (anomalous) Hall current J H appears transverse to E (in practice, a weak H serves to align the magnetic domains) (1,2). Questions regarding the origin of J H , and whether it is dissipationless, have been keenly debated for decades. They have emerged anew because of fresh theoretical insights and strong interest in spin currents for spin-based electronics. Here we report measurements in the ferromagnet CuCr 2 Se 4−x Br x which establish that, despite a 100-fold increase in the scattering rate from impurities, J H (per carrier) remains constant, implying that it is indeed dissipationless.In 1954, Karplus and Luttinger (KL)(3,4) proposed a purely quantum-mechanical origin for J H . An electron in the conduction band of a crystal lattice spends part of its time in nearby bands because of admixing caused by the (intracell) position operator X. In the process, it acquires a spin-dependent 'anomalous velocity' (5). KL predicted that the Hall current is dissipationless: J H remains constant even as the longitudinal current (J||E) is degraded by scattering from added impurities. A conventional mechanism was later proposed (6) whereby the anomalous Hall effect (AHE) is caused instead by asymmetric scattering of electrons by impurities (skew scattering). Several authors (7,8,9) investigated the theoretical ramifications of these competing models. The role of impurities in the anomalous-velocity theory was clarified by Berger's side-jump model (7 AHE in a semiconductor has been given by Nozières and Lewiner (NL) who derive X = λk × S, with λ the enhanced spin-orbit parameter, k the carrier wavevector and S its spin (9). In the dc limit, NL obtain the AHE currentwhere n is the carrier density and e the charge. As noted, J H is linear in S but independent of the electron lifetime τ . In modern terms, the anomalous velocity term of KL is related to the Berry phase (10), and has been applied (11) to explain the AHE in Mn-doped GaAs (12). The close connection of the AH...
