["E‒Cr‒Fe system (E = Sb, Bi) We focus on the difference of Lewis acidity and reactivity between the reported 4-center, 6uf070-conjugated unsaturated trigonal-planar complex, [E{Cr(CO)5}3]– (E = Sb, 1; Bi, 2). When 1 was reacted with weak nucleophile H2O, Lewis adduct [(HO)Sb{Cr(CO)5}3]2‒ (1-OH) was formed. However, 2 was unreacted with H2O, showing the greater Lewis acidity of 1 than that of 2, which was further supported by DPV studies. Since the oxidation state of Bi in 2 was previously determined to be +3, the oxidation state of Sb in 1 was assigned in 0 by X-ray photoelectron spectroscopy (XPS). The strong Lewis acidity of 1 may be attributed to its electronic unsaturated character, even if the Sb atom was electron-rich. In addition, when 2 was treated with [HFe(CO)4]–, the tetrahedral complex [{Fe(CO)4}Bi{Cr(CO)5}3]3– (2-Fe) was obtained which can further react with [FeCp2][PF6] to produce [{Cr(CO)5}2Bi2{Fe(CO)3}3]2‒ (4) via a mixrd Cr–Fe trigonal-planar intermediate [Bi{Cr(CO)5}2{Fe(CO)4}]– (3). On the other hand, similar reaction of 1 with [HFe(CO)4]– led to the formation of a mixture of [(H)Sb{Cr(CO)5}2{Fe(CO)4}]2‒ (1-Fe) and [(H)Sb{Cr(CO)5}3]2‒ (1-H). This distinct reaction pattern was deduced to the different electronegativity and atomic size between the Sb and Bi atoms. Interestingly, the treatment of the 1-Fe with excess HBF4 at room temperature afforded the coupling product [FSb2{Cr(CO)5}3{Fe(CO)4}2]‒ (6). While the deprotonation of 1-Fe with 1 equivalent of [CPh3][BF4] at ‒30 oC gave rise to the complex [Sb2{Cr(CO)5}4{Fe(CO)4}2]2‒ (7), the treatment with 1.5 equivalents of [CPh3][BF4] resulted in the formation of a mixture of [(HO)Sb2{Cr(CO)5}3{Fe(CO)4}2]‒ (8) and 6. Finally, the reaction mechanism and electronic structures of 1 and 2 were elucidated with the aid of density functional theory (DFT) calculations. E‒Fe-Hg-Cu system (E = S, Se) When [PPh4]2[SeFe3(CO)9] was treated with 2 equiv of Hg(OAc)2 in MeCN solution at –30 oC, the Hg-bridged di-SeFe3 cluster [PPh4]2[{(μ3-Se)Fe3(CO)9}Hg{(μ4-Se)Fe3(CO)9}] ([PPh4][2]) was obtained. Furthermore, the reaction of [PPh4][2] with [{Cu(MeCN)2(dpy)}{BF4}]n (1) via liquid-assisted grinding (LAG) led to the formation of [{Cu(dpy)(MeCN)2}{Cu(dpy)1.5(MeCN)}{{(uf06d3-Se)Fe3(CO)9}2Hg}]n (4). Similar reaction of [Et4N]2[{SFe3(CO)9}2Hg] with 1 via LAG produced structural isomers [{Cu(dpy)(MeCN)}2{(uf06d4-S)Fe3(CO)9}2Hg]n (3 and 3'), as evidenced by XRD and PXRD analyses. Interestingly, the solid-state packings showed that the unexpected non-classical C‒H…O (carbonyl) hydrogen bonds existed in the frameworks of the series of EFe3Hg-Cu (E = S, Se, Te) polymers, which can be regarded to facilitate the electron transport. The intriguing structure-property relationships were demonstrated by the significant change in the oxidation state of Cu atom by X-ray photoelectron spectroscopy (XPS) and X-ray absorption near-edge structure spectroscopy (XANES)."]