The linear [chi((1))] and second-order nonlinear [chi((2))] optical susceptibilities of the 2-methyl-4-nitroaniline (MNA) crystal are calculated within the local field theory, which consists of first computing the molecular properties, accounting for the dressing effects of the surroundings, and then taking into account the local field effects. Several aspects of these calculations are tackled with the aim of monitoring the convergence of the chi((1)) and chi((2)) predictions with respect to experiment by accounting for the effects of (i) the dressing field within successive approximations, of (ii) the first-order ZPVA corrections, and of (iii) the geometry. With respect to the reference CCSD-based results, besides double hybrid functionals, the most reliable exchange-correlation functionals are LC-BLYP for the static chi((1)) and CAM-B3LYP (and M05-2X, to a lesser extent) for the dynamic chi((1)) but they strongly underestimate chi((2)). Double hybrids perform better for chi((2)) but not necessarily for chi((1)), and, moreover, their performances are much similar to MP2, which is known to slightly overestimate beta, with respect to high-level coupled-clusters calculations and, therefore, chi((2)). Other XC functionals with less HF exchange perform poorly with overestimations/underestimations of chi((1))/chi((2)), whereas the HF method leads to underestimations of both. The first-order ZPVA corrections, estimated at the B3LYP level, are usually small but not negligible. Indeed, after ZPVA corrections, the molecular polarizabilities and first hyperpolarizabilities increase by 2% and 5%, respectively, whereas their impact is magnified on the macroscopic responses with enhancements of chi((1)) by up to 5% and of chi((2)) by as much as 10%-12% at lambda = 1064 nm. The geometry plays also a key role in view of predicting accurate susceptibilities, particularly for push-pull pi-conjugated compounds such as MNA. So, the geometry optimized using periodic boundary conditions is characterized by an overestimated bond length alternation, which gives larger molecular properties and even larger macroscopic responses, because of the local field factor amplification effects. Our best estimates based on experimental geometries, charge dressing field, ZPVA correction, and CCSD molecular properties lead to an overestimation chi((1)) by 12% in the static limit and 7% at lambda = 1064 nm. For chi((2)), the difference, with respect to the experiment, is satisfactory and of the order of one standard deviation.

• 出版日期2014-5