EPJ B Highlight - Silver Sheds Light On Superconductor Secrets

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Published on 10 January 2013

By doping a bismuth-based layered material with silver, Chinese scientists demonstrated that superconductivity is intrinsic to the new material rather than stemming from its impurities

The first report on the chemical substitution, or doping, using silver atoms, for a new class of superconductor that was only discovered this year, has just been published in EPJ B. Chinese scientists from Institute of Solid State Physics, Chinese Academy of Sciences, Hefei, discovered that the superconductivity is intrinsic rather than created by impurities in this material with a sandwich-style layered structure made of bismuth oxysulphide (Bi₄O₄S₃).

Superconductors with a transition temperature (T_C) above the boiling temperature of liquid nitrogen (77 kelvins or −196 °C) are called high T_C superconductors. In the quest for such materials, compounds with bismuth disulphide (BiS₂) layers have recently started to attract a lot of attention. Indeed, in July 2012, Japanese scientists reported achieving a T_C at around 4.5 kelvins (-268.65 °C) with the first bismuth oxysulphide superconductor.

All the superconducting samples for this new superconductor reported so far are a mixture of Bi₄O₄S₃ and impurities. However, the pure sample without impurities is not superconducting. Scientists have therefore been wondering whether the observed superconductivity stems from the presence of impurities.

The Hefei team performed systematic measurement of the material’s characteristics relying on x-ray diffraction, magnetic susceptibility, electrical transport and thermal transport. Using comparison of the x-ray diffraction patterns, they found that silver atoms partially replace the bismuth sites in the bismuth oxysulphide lattice.

Further experiments involved controlling the composition of the material through various levels of silver doping. The superconductivity, the authors found, was suppressed as the silver content increases and eventually disappears above a certain doping threshold. They believe that it is the modification of electronic structure upon doping that suppresses the superconductivity.

Based on these observations, they concluded that the observed superconductivity originates from the bismuth oxysulphide lattice rather than any impurities.