Spin-dependent magnetoresistance in multiwall carbon nanotubes

The spin-dependent transport in multiwall carbon nanotubes, obtained by chemical vapour deposition in porous alumina membranes, has been investigated. The zero-bias anomaly is shown to follow the typical power law $GT^{-{\alpha}}(eV/kT)$. In the nanotubes contacted with $\chem{Ni}$ pads, the magnetoresistance due to the spin-polarised current (SD-MR) is destroyed. In the case of those contacted with $\chem{Co}$ pads, however, the SD-MR is observed. These measurements show that both the observation of a typical scaling law of the conductance (for nanotubes up to 1.5$\un{\mu m}$) and a short spin diffusion length (less than 0.15$\un{\mu m}$ with nickel contacts and 0.7$\un{\mu m}$ with cobalt contacts) coexist through the nanotube. This observation may be interpreted in terms of a reminiscence of the Luttinger-liquid behaviour with spin-charge separation.