The Lewis diagram for NCN2- showing the symmetric carbodiimide form (1) and the asymmetric cyanamide form (2)
Inorganic carbodiimides (or cyanamides depending on the NCN2- form) design a family of compounds containing the carbodiimide (or cyanamide) anion NCN2- bonded to an inorganic group such as a metal. This anion exhibits pseudochalcogenide character.[1]
Crystal structure of TNCN, M= Fe, Co, Ni
History
Adolph Frank and Nikodem Caro were the first to synthesize calcium cyanamide (CaNCN) and to develop a route for its production at the industrial level in 1898.[2] But, the very first beginning of the metal carbodiimides/cyanamides goes back to the 1870s. One can find detailed reports by E. Drechsel on the preparation of Ag2NCN, CaNCN, BaNCN, K2NCN and Li2NCN between 1875 and 1898 (before even XRD invention).[3][4] The preparation of Cd, Zn, Tl, Cu, Pb and Hg carboimides has been described during the 1950s. CaNCN is by the far the most known since it has been produced since 1898 and used as a fertilizer.
Starting from 2000s, rare earth metal carbodiimides Ln2(NCN)3 (Ln = La, Ce, Nd, Pm, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm and Tm)[5] and transition metal carbodiimides TNCN (T= Mn, Fe, Co, Ni, Cu) and Cr2(NCN)3have been reported.[6] Non-metallic carbodiimides are also known such as Si(NCN)2.[7]
Structure
Tx(NCN)y binaries adopt generally structures with cationic layers made of octahedrally coordinated T2+/T3+ cations alternating with anionic layers of NCN2– in various structures such as rock-salt, NiAs- and NaN3-like structures. A side of binary carbodiimides, ternary (SrZn(NCN)2) and quaternary ones (Li2Sm2Sr(NCN)5 ) have also been prepared via solid-state metathesis.
Dimorphism is observed in inorganic carbodiimide. HgNCN for example can adopt two structures with two different NCN configurations, this means that HgNCN can have either carbodiimide[8] or cyanamide[9] structures.
Electrochemical performance of FeNCN as anode material for Li-ion batteries
Recently, metal carbodiimides are explored as anode materials for lithium and sodium ion batteries and found to present better specific capacities compared to conventional graphite and hard carbon electrode materials.[10][11]
^"Über ein neues Verfahren zur Erzeugung hoher Temperaturen und zur Darstellung von schwer schmelzbaren kohlefreien Metallen". Zeitschrift für Elektrotechnik und Elektrochemie. 4 (21): 494–499. 1898-05-05. doi:10.1002/bbpc.18980042105. ISSN0372-8323.
^Drechsel, E. (1880-01-05). "Beiträge zur Kenntniss des Cyanamids;. II. Abhandlung". Journal für Praktische Chemie. 21 (1): 77–97. doi:10.1002/prac.18800210104. ISSN0021-8383.
^Liu, Xiaohui; Krott, Manuel; Müller, Paul; Hu, Chunhua; Lueken, Heiko; Dronskowski, Richard (May 2005). "Synthesis, Crystal Structure, and Properties of MnNCN, the First Carbodiimide of a Magnetic Transition Metal†". Inorganic Chemistry. 44 (9): 3001–3003. doi:10.1021/ic050050a. ISSN0020-1669. PMID15847401.
^Riedel, Ralf; Greiner, Axel; Miehe, Gerhard; Dressler, Wolfgang; Fuess, Hartmut; Bill, Joachim; Aldinger, Fritz (1997). "The First Crystalline Solids in the Ternary Si-C-N System". Angewandte Chemie International Edition in English. 36 (6): 603–606. doi:10.1002/anie.199706031. ISSN1521-3773.
^Liu, Xiaohui; Müller, Paul; Kroll, Peter; Dronskowski, Richard (2002-08-01). "Synthesis, Structure Determination, and Quantum-Chemical Characterization of an Alternate HgNCN Polymorph". Inorganic Chemistry. 41 (16): 4259–4265. doi:10.1021/ic020133g. ISSN0020-1669. PMID12160416.
