Te－Fe－Cu－L (L = NHC or N-alkyl imidazole) System When [TeFe3(CO)9]2─ was treated with [Cu(MeCN)4][BF4] and 1-methylimidazole (MeIm) or annulated 1-methylbenzimidazole (MeBzIm) in the molar ratio of 1: 1: 1 or 1: 2: 2, a series of Cu(I)-linked, TeFe3-based clusters bearing imidazole ligand(s) [TeFe3(CO)9Cu(MeIm)]─ (1), [TeFe3(CO)9Cu2(MeIm)2] (2), [TeFe3(CO)9Cu(MeBzIm)]─ (3), [TeFe3(CO)9Cu2(MeBzIm)2] (4), and [(TeFe3(CO)9Cu)2(BzIm)]3─ (7) were obtained. To investigate the influence on the electronic properties of NHCs and N-methyl imidazole ligands and the difference arisen from normal imidazole or annulated imidazole ligand in metal clusters, imidazole-containing complexes 2 and 4 were compared with NHC complexes [TeFe3(CO)9Cu2(Me2Im)2] (6) and [TeFe3(CO)9Cu2(Me2BzIm)2] (8) in terms of electrochemistry, UV-vis spectrum, and catalytic homo-coupling reaction with the aid of DFT calculations. E－Fe－Bi (E = Se, Te) System When mixed group 15/16 square pyramidal cluster [SeBiFe3(CO)9]─ (1a) was refluxed in MeCN, a tetrahedral cluster [SeBiFe2(CO)6]─ (2a) was formed. Similar tetrahedral cluster [TeBiFe2(CO)6]─ (2b) could be generated from the reaction of [TeBiFe3(CO)9]─ (1b) with 1 equiv NaBiO3 in refluxing MeCN. The treatment of 1a with the oxidizing reagent, K2SeO3, in MeCN/MeOH solution could form a novel cluster [Bi(Se2Fe2(CO)6)2] (3) which displayed a double Se2Fe2(CO)6 butterfly structure with a bridging 4-Bi atom. In addition, complex 1a could react with Ru3(CO)12 in the molar ratio of 2: 1 to produce a mixed-metal octahedral cluster [SeBiFeRu3(CO)11]─ (4). To further investigate the influence of mixed group 15/16 elements and the role of Bi, a series of group 16 clusters, [E2Fe2(CO)6] (E = Se, Te) and [E2Fe3(CO)9] (E = Se, Te), were synthesized and compared with the isoelectronic mixed-main group clusters, [EBiFe2(CO)6]─ (E = Se, 2a; Te, 2b) and [EBiFe3(CO)9]─ (E = Se, 1a; Te, 1b), in terms of electrochemistry and UV-vis spectrum with the aid of DFT and TD-DFT calculations. Besides, the parallel comparison was also applied to [ERu5(CO)14]2─ (E = Se, Te) and its structural analogues [SeBiFeRu3(CO)11]─ (4) and [TeBiRu4(CO)11]─ via spectroscopic method and theoretical calculations.