Films of ZnO doped with magnetic ions, Mn and Co and, in some cases, with Al have been fabricated with a very wide range of carrier densities. Ferromagnetic behaviour is observed in both insulating and metallic films, but not when the carrier density is intermediate. Insulating films exhibit variable range hopping at low temperatures and are ferromagnetic at room temperature due to the interaction of the localised spins with static localised states. The magnetism is quenched when carriers in the localised states become mobile. In the metallic (degenerate semiconductor) range, robust ferromagnetism reappears together with very strong magneto-optic signals and room temperature anomalous Hall data. This demonstrates the polarisation of the conduction bands and indicates that, when ZnO is doped into the metallic regime, it behaves as a genuine magnetic semiconductor. PACS numbers 75.50.Pp, 78.20.Ls, 73.61 The search for spintronic materials that combine both semiconducting and ferromagnetic properties is currently one of the most active research fields in magnetism. Compounds based on ZnO are especially exciting in this context since, in contrast to GaMnAs and InMnAs, they exhibit ferromagnetism at room temperature [1][2][3][4][5][6][7]. Despite the progress in developing ZnO as a spintronic material, there has been much controversy concerning the mechanism that causes the magnetism [8][9][10]. It has been found that not all doped films exhibit ferromagnetism, and that the mobile carrier density, n c , can be very different in those compounds that do. This implies that the established theory of carrier-mediated magnetism, which works well for ptype GaMnAs, is not generally applicable to this n-type material. For example, it has been found that the addition of Zn interstitials, which affects both the number of neutral and ionised donors, leads to an increase in the ferromagnetism [11], and a recent study of Al-doped ZnCoO has reported a variation of magnetisation with Al content rather than carrier density [12]. In fact, most of the work on doped ZnO has concentrated on the insulating phase [9,[13][14][15], to such an extent that some authors now refer to ZnO as a dilute magnetic insulator (DMI) [13].However, we have recently reported the observation of ferromagnetism in Al-doped films where n c is very high [16], which highlights the importance of exploring the full range of carrier densities from the insulating to the metallic phases.In this Letter we report a systematic study of the relationship between the magnetism and conductivity in transition metal (TM) doped ZnO. By studying a large number of films with a wide range of carrier densities, we have identified three distinct conductivity regimes:1. The insulating phase at low carrier densities, in which the conductivity at low temperatures arises from a variable range hopping (VRH) process [17]. In this regime, labelled VRH, the least conducting films are the most magnetic, as has been observed previously [13,14]. 2. The intermediate regime, labelled I,...
