Semiconducting transport in Pb10-xCux(PO4)6O sintered from Pb2SO5 and Cu3P

Abstract

The very recent claim on the discovery of ambient-pressure room-temperature superconductivity in modified lead-apatite has immediately excited sensational attention in the entire society, which is fabricated by sintering lanarkite (Pb2SO5) and copper(I) phosphide (Cu3P). To verify this exciting claim, we have successfully synthesized Pb2SO5, Cu3P, and finally the modified lead-apatite Pb10-xCux(PO4)6O. Detailed electrical transport and magnetic properties of these compounds were systematically analyzed. It turns out that Pb2SO5 is a highly insulating diamagnet with a room-temperature resistivity of ~7.18x109 Ohm.cm and Cu3P is a paramagnetic metal with a room-temperature resistivity of ~5.22x10-4 Ohm.cm. In contrast to the claimed superconductivity, the resulting Pb10-xCux(PO4)6O compound sintered from Pb2SO5 and Cu3P exhibits semiconductor-like transport behavior with a large room-temperature resistivity of ~1.94x104 Ohm.cm although our compound shows greatly consistent x-ray diffraction spectrum with the previously reported structure data. In addition, when a pressed Pb10-xCux(PO4)6O pellet is located on top of a commercial Nd2Fe14B magnet at room temperature, no repulsion could be felt and no magnetic levitation was observed either. These results imply that the claim of a room-temperature superconductor in modified lead-apatite may need more careful re-examination, especially for the electrical transport properties.