Unconventional Magnetic Oscillations in Kagome Mott Insulators

We apply a strong magnetic field to a kagome Mott insulator with antiferromagnetic interactions which does not show magnetic ordering down to low temperatures. We observe a plateau at magnetization 1/9 Bohr magneton per magnetic ion (Cu). Furthermore, in the vicinity of this plateau we observe sets of strong oscillations in the magnetic torque, reminiscent of quantum oscillations in metals. Such oscillations have never been seen in a wide gap insulator and point to an exotic origin. While the temperature dependence of these oscillations follows Fermi-liquid-theory predictions, they are approximately periodic in the magnetic field $H$, as opposed to $1/H$ in conventional metals. Furthermore, a strong angular dependence is observed for the period, which indicates an orbital origin for this effect. We show that the 1/9 plateau and the associated oscillations are consistent with the appearance of a quantum-spin-liquid state whose excitations are fermionic spinons that obey a Dirac spectrum. The oscillations are in response to an emergent gauge field. Our results provide strong evidence that fractionalized particles coupled to the elusive emergent gauge field have been observed.