Transmission of radio-frequency waves and nuclear magnetic resonance in lanthanum superhydrides
Abstract
The discovery of near-room temperature superconductivity in the lanthanum hydride LaH10 has revolutionized this field of research. However, the need to use diamond anvils for the synthesis of such superconductors severely limits the number of experimental techniques to study these materials. Nuclear magnetic resonance (NMR) is one of the key methods for probing spin systems of superconductors. In this work, we show how 1H NMR measurements can be realized in diamond anvil cells to study high-temperature superconductivity in lanthanum polyhydrides at pressures up to 165 GPa. In the newly discovered superhydride LaH12, we observed a pronounced suppression of the 1H NMR signal intensity below Tc(onset) = 260 K in a magnetic field of 7 T, corresponding to the screening of the radio-frequency pulses. Below the critical temperature of superconductivity, all 1H NMR characteristics, including the spin-lattice relaxation rate 1/T1T, demonstrate pronounced features, evidencing the bulk nature of the superconducting transition. In zero field, the radio-frequency signal transmission through the LaH12 sample shows a pronounced drop below Tc(onset) = 267 K, confirming the superconducting nature of the transition. A description of the 1/T1T data with an exponential form allows the estimation of the superconducting gap (0) lying between 427 and 671 K (corresponding to 36.8 to 57.8 meV), and the ratio R = 2(0)/kBTc between 3.76 and 5.16 in the synthesized hydride sample.
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