The self-dual random-bond eight-state Potts model is studied numerically through large-scale Monte Carlo simulations using the Swendsen-Wang cluster flipping algorithm. We compute bulk and surface order parameters and susceptibilities and deduce the corresponding critical exponents at the random fixed point using standard finite-size scaling techniques. The scaling laws are suitably satisfied. We find that a belonging of the model to the 2D Ising model universality class can be conclusively ruled out, and the dimensions of the relevant bulk and surface scaling fields are found to take the values y h = 1.849, yt = 0.977, y hs = 0.54, to be compared to their Ising values: 15/8, 1, and 1/2.The understanding of the role played by impurities on the nature of phase transitions is of great importance, both from experimental and theoretical perspectives. It is a quite active field of research where the resort to large-scale Monte Carlo simulations is often necessary [1]. The effect of quenched bond randomness in a system which undergoes, in the homogeneous case, a secondorder phase transition has been extensively studied. It is well understood since Harris proposed a relevance criterion for the fluctuating interactions [2]. Disorder appears to be a relevant perturbation when the specific heat exponent α of the pure system is positive. Since in the two-dimensional Ising model (IM) α vanishes due to the logarithmic Onsager singularity, this model was carefully studied in the '80s [3].The analogous situation when the pure system exhibits a first-order transition was less well studied, in spite of the early work of Imry and Wortis who argued that quenched disorder could induce a secondorder phase transition [4]. This argument was then rigourously proved by Aizenman and Wehr, and Hui and Berker [5]. In two dimensions, even an infinitesimal amount of quenched impurities changes the transition into a second-order one. The first intensive Monte Carlo study of the effect of disorder at a first-order phase transition is due to Chen, Ferrenberg and Landau (CFL). These authors studied the q = 8-state two-dimensional Potts model, which, in the pure case, is known to exhibit a first-order phase transition when q > 4 [6]. They definitively showed that the transition becomes secondorder in the presence of bond randomness [7], and obtained the critical exponents from a finite-size scaling (FSS) study at the critical point of a self-dual disordered system [8]. Their results, together with other related works [10,11], suggested that any two-dimensional random system should belong to the 2D pure IM universality class [12]. In a recent paper, Cardy and Jacobsen (CJ) used a different approach [13], based on a transfer matrix formalism [14], to study random-bond Potts models for different values of q. Their estimation of the critical exponents leads to a continuous variation of β b /ν with q. This result is in accordance with previous theoretical calculations when q ≤ 4 [15], and, in the randomnessinduced second-order phase transition regime q...
