Collections of interacting spins typically arrange themselves into ordered magnetic patterns at low temperature. Certain materials, however, evade ordering even at absolute zero, giving way to quantum spin-liquid phases supporting “fractionalized” excitations that behave like spins nontrivially diced into pieces. Recent experiments indicate that the insulating compound $\alpha \text{−}{\mathrm{RuCl}}_3$ can produce a particularly enticing quantum spin liquid whose fractionalized excitations include so-called “non-Abelian anyons,” a class of quasiparticles that enable intrinsically error-resilient quantum computing. We provide a critical step toward harnessing this technological promise by introducing experiments that electrically probe the spin liquid’s fractionalized excitations even though the platform itself forms a good electrical insulator.

Electronic probes of fractionalization are well developed for many electrically active systems, but these tools do not naturally import to spin liquids because of their insulating character. We show that this barrier can be overcome by connecting conducting circuit elements to the quantum spin liquid in a manner that enables perfect conversion of electrons into fractionalized excitations and vice versa. Remarkably, nucleating even a single excitation in the spin liquid then qualitatively alters the circuit’s electrical conductance, providing unambiguous electrical fingerprints of fractionalized excitations as well as their nontrivial exchange statistics.

Our work spotlights quantum spin liquids as appealing contenders for fault-tolerant quantum-computing hardware. We anticipate further theoretical and experimental work aimed at developing a detailed road map toward applications in this arena.