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Super-rough phase of the random-phase sine-Gordon model: Two-loop results

We consider the two-dimensional random-phase sine-Gordon and study the vicinity of its glass transition temperature $T_c$, in an expansion in small $τ=(T_c-T)/T_c$, where $T$ denotes the temperature. We derive renormalization group equations in cubic order in the anharmonicity, and show that they contain two universal invariants. Using them we obtain that the correlation function in the super-rough phase for temperature $T<T_c$ behaves at large distances as $\bar{<[θ(x)-θ(0)]^2>} = \mathcal{A}\ln^2(|x|/a) + \mathcal{O}[\ln(|x|/a)]$, where the amplitude $\mathcal{A}$ is a universal function of temperature $\mathcal{A}=2τ^2-2τ^3+\mathcal{O}(τ^4)$. This result differs at two-loop order, i.e., $\mathcal{O}(τ^3)$, from the prediction based on results from the &#34;nearly conformal&#34; field theory of a related fermion model. We also obtain the correction-to-scaling exponent.