Information scrambling and the butterfly effect in chaotic quantum systems
can be diagnosed by out-of-time-ordered (OTO) commutators through an
exponential growth and large late time value. We show that the latter feature
shows up in a strongly correlated many-body system, a Luttinger liquid, whose
density fluctuations we study at long and short wavelengths, both in
equilibrium and after a quantum quench. We find rich behaviour combining
robustly universal and non-universal features. The OTO commutators display
temperature and initial state independent behaviour, and grow as t2 for
short times. For the short wavelength density operator, they reach a sizeable
value after the light cone only in an interacting Luttinger liquid, where the
bare excitations break up into collective modes. We benchmark our findings
numerically on an interacting spinless fermion model in 1D, and find
persistence of central features even in the non-integrable case. As a
non-universal feature, the short time growth exhibits a distance dependent
power.Comment: 6 pages, 2 figure
