Abstract

Abstract Dissolution of ytterbium metal in liquid ammonia in the presence of carbazole at low temperatures and subsequent treatment with N‐phenylpiperazine gives single crystalline [Yb(Cbz) 2 (NH 3 ) 4 ] · 3Phpip (Cbz − = carbazolate anion, C 12 H 8 N − , Phpip = N‐phenylpiperazine, (C 6 H 5 )C 4 H 8 NNH). The highly air and moisture sensitive crystals are prone to release ammonia but can be successfully shielded in the interior of large crystals of CbzH · Phpip, a co‐crystallization of both ligands, whose crystal structure is also presented. Further heating transforms the monomeric molecules [Yb(Cbz) 2 (NH 3 ) 4 ] into dimeric [Yb 2 (Cbz) 4 (NH 2 ) 2 (NH 3 ) 4 ] · 3CbzH and their condensation accompanied by release of ammonia consequently leads to the coordination polymer $^{1}_{\infty}\rm [Yb_{2}(Cbz)_{4}]$ . This reaction path is compared to a high temperature reaction route without electride formation. Synthesis in molten carbazole directly leads to the one‐dimensional coordination polymer. Subsequent treatment with N‐phenylpiperazine yields dimeric [Yb 2 (Cbz) 4 (Phpip) 4 ] · 2Phpip and monomeric [Yb(Cbz) 2 (Phpip) 3 ][Yb(Cbz) 3 (Phpip) 2 ], the final step of the degradation reaction. It can be shown that N‐phenylpiperazine functions as chemical scissors at higher temperatures and as crystallization matrix at lower temperatures.