Multicomponent Kardar-Parisi-Zhang Universality in Degenerate Coupled Condensates
Abstract
We show that the multicomponent Kardar-Parisi-Zhang equation describes the low-energy theory for phase fluctuations in a Z2 degenerate non-equilibrium driven-dissipative condensate with global U(1)× U(1) symmetry. Using dynamical renormalisation group in spatial dimension d=1, we demonstrate that coupled stochastic complex Ginsburg-Landau equations exhibit an emergent stationary distribution, enforcing KPZ dynamical exponent z=3/2 and static roughness exponent =1/2 for both components. By tuning intercomponent interactions, the system can access other regimes, including a fragmented condensate regime from a dynamical instability in the phase fluctuations, as well as a spacetime vortex regime driven by the non-linear terms in the coupled KPZ equations. In stable regimes, we show that in specific submanifolds relevant to polaritons, the RG fixed point offers a transformation to decoupled KPZ equations. Our findings have broad implications for understanding multicomponent KPZ systems in the long-wavelength limit.
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