Emergent moments and random singlet physics in a Majorana spin liquid

Abstract

We exhibit an exactly solvable example of a SU(2) symmetric Majorana spin liquid phase, in which quenched disorder leads to random-singlet phenomenology. More precisely, we argue that a strong-disorder fixed point controls the low temperature susceptibility (T) of an exactly solvable S=1/2 model on the decorated honeycomb lattice with quenched bond disorder and/or vacancies, leading to (T) = C/T+ D Tα(T) - 1 where α(T) → 0 as T → 0. The first term is a Curie tail that represents the emergent response of vacancy-induced spin textures spread over many unit cells: it is an intrinsic feature of the site-diluted system, rather than an extraneous effect arising from isolated free spins. The second term, common to both vacancy and bond disorder (with different α(T) in the two cases) is the response of a random singlet phase, familiar from random antiferromagnetic spin chains and the analogous regime in phosphorus-doped silicon (Si:P).