Abstract EN:

We have studied the modifications in the behaviour of the electron gas at low temperatures and the ground state of single-chain quasi-1d conductors (TMTSF)2X associated with the presence of non-centrosymmetric anions (X). The ground states can be either insulating (due to the formation of a spin density wave phase or ta the anion ordering), or superconducting, or even metallic. Our study confirms the important role of pressure in establishing the SC ground state and shows the dominant effect of non-magnetic impurities on the mutual stability of SC and AF phases. Applied pressure provides the conditions necessary for SC coupling and transforms staggered anion ordering into an uniform one compatible with the metallic behaviour and the SC ground state. However in those compounds with dipolar anions or in the alloys, the SC ground state is easily suppressed due to the strong random potential along the conducting chains which is created by the anions. Moreover, the degree of order on the anion chains plays a decisive role in the competition between the AF and SC phases: the disorder favours the former, while a uniform order is compatible with the latter. We discuss the extreme sensitivity of the superconductivity ta the presence of non-magnetic defects in the framework of two theoretical models depending on whether the SC ground state is singlet or triplet. However, the proximity of the AF and SC ground states in the phase diagram, as well as the fact that the magnetic susceptibility is almost temperature independent are somewhat more compatible with triplet pairing. Nevertheless, independently of the nature of the SC ground state we conclude that a one-particle approach is too restrictive and that an analysis taking into account cooperative precursor effects is necessary to understand the unusual properties of the SC ground state in the (TMTSF)2X compounds and their alloys.