The synthesis, and the structural and magnetic properties, of the following new iron(III) Schiff base complexes with the {O',N,O ''}-chelating ligand H2L (2-hydroxyphenylsalicylaldimine) are reported: K[FeL2].H2O (1), (Pr3NH)[FeL2](2)CH3OH (2), [FeL(bpyO(2)) (CH3OH)][FeL2]CH3OH (3), [Fe2L3(CH3OH)](2)CH3OH center dot H2O (4), and [{Fe2L2}(mu-OH)(2){Fe2L2}(bpyO(2))}2}[BPh4](2)center dot 2H(2)O (5), where Pr3N1-1 represents the tripropylammonium cation and bpyO(2) stands for 2,2'-bipyridineN-dioxide. A thorough density functional theory (DFT) study of magnetic interactions (the isotropic exchange) at the B3LYP/def-TZVP level of theory was employed, and calculations have revealed superexchange pathways through intramolecular/intermolecular noncovalent contacts ( stacking, C H center dot center dot center dot O and O-H center dot center dot center dot O hydrogen bonds, diamagnetic metal cations) and/or covalent bonds ((mu-Oph, mu-OH) or bis(mu-O-Ph) bridging modes), which helped us to postulate trustworthy spin Hamiltonians for magnetic analysis of experimental data. Within the reported family of compounds 1-5,, the mediators of the antiferromagnetic exchange can be sorted by their increasing strength as follows: g g stacking OD FT. -0.022 cm(-1) Vfnag = 0.025(4) cm(-1) in 2) < C-H center dot center dot center dot O contacts and pi-pi stacking (J(DFT) = 0.19 cm-(1) /J(mag) = 0.347(9)cm(-1) in 1) < O-H center dot center dot center dot O hydrogen bonds unFT = 0.53 cm(-1) /J(mag) = 0.41(1) cm(-1) in 3) < bis(mu-O-ph) bridge (J(DFT) = 13.8 cm(-1) VJ(ma) = 12.3(9) cm(-1) in 4) < (mu-O-ph, mu-OH) bridge (J(DFT) = -18.0 cm-(1) /J(mag) = 17.1(2) cm i in 5), where J(DFT) and rag are the isotropic exchange parameters derived from DFT calculations, and analysis of the experimental magnetic data, respectively. The good agreement between theoretically calculated and experimentally derived isotropic exchange parameters suggests that this procedure is applicable also for other chemical and structural systems to interpret magnetic data properly.