Magnetic-Field Response and Giant Electric-Field Modulation of Cu 2 S.

Cu 2 S likely plays an important role in the sharp resistivity transition of LK-99. Nevertheless, this immediately arouses an intriguing question of whether the extraordinary room-temperature colossal magnetoresistance in the initial reports, which has been less focused, originates from Cu 2 S as well. To resolve this issue, we have systematically investigated the electrical transport and magnetotransport properties of near-stoichiometric Cu 2 S pellets and thin films. Neither Cu 2 S nor LK-99 containing Cu 2 S in this study was found to exhibit the remarkable magnetoresistance effect implied by Lee et al. This implies that Cu 2 S could not account for all of the intriguing transport properties of the initially reported LK-99, and the initially reported LK-99 samples might contain magnetic impurities. Moreover, based on the crystal-structure-sensitive electrical properties of Cu 2 S, we have constructed a piezoelectric-strain-controlled device and obtained a giant and reversible resistance modulation of 2 orders of magnitude at room temperature, yielding a huge gauge factor of 160,000.