“Dihydrogen bond”的意思、由来-开放百科全书

In chemistry, a dihydrogen bond is a kind of hydrogen bond, an interaction between a metal hydride bond and an OH or NH group or other proton donor. With a van der Waals radius of 1.2 Å, hydrogen atoms do not usually approach other hydrogen atoms closer than 2.4 Å. Close approaches near 1.8 Å, are, however, characteristic of dihydrogen bonding.^[1]

Boron hydrides

An early example of this phenomenon is credited to Brown and Heseltine.^[1] They observed intense absorptions in the IR bands at 3300 and 3210 cm⁻¹ for a solution of (CH₃)₂NHBH₃. The higher energy band is assigned to a normal N−H vibration whereas the lower energy band is assigned to the same bond, which is interacting with the B−H. Upon dilution of the solution, the 3300 cm⁻¹ band increased in intensity and the 3210 cm⁻¹ band decreased, indicative of intermolecular association.

Interest in dihydrogen bonding was reignited upon the crystallographic characterization of the molecule H₃NBH₃. In this molecule, like the one studied by Brown and Hazeltine, the hydrogen atoms on nitrogen have a partial positive charge, denoted H^δ+, and the hydrogen atoms on boron have a partial negative charge, often denoted H^δ−.^[2] In other words, the amine is a protic acid and the borane end is hydridic. The resulting B−H^...H−N attractions stabilize the molecule as a solid. In contrast, the related substance ethane, H₃CCH₃, is a gas with a boiling point 285 °C lower. Because two hydrogen centers are involved, the interaction is termed a dihydrogen bond. Formation of a dihydrogen bond is assumed to precede formation of H₂ from the reaction of a hydride and a protic acid. A very short dihydrogen bond is observed in NaBH₄·2H₂O with H−H contacts of 1.79, 1.86, and 1.94 Å.^[3]

Coordination chemistry

In neutral compounds

So-called hydrogen hydrogen bond interactions have been proposed to occur between two neutral non-bonding hydrogen atoms from Atoms in molecules theory, while similar interactions have been shown to exist experimentally.^[6] Many of these types of dihydrogen bonds have been identified in molecular aggregates.^[7]

Notes

1. ^{{Cite journal| volume = 23| pages = 1551–1552iskandar| last = Brown| first = M. P.|author2=Heseltine, R. W.| title = Co-ordinated BH3 as a proton acceptor group in hydrogen bonding| journal = Chem. Commun.| year = 1968| doi = 10.1039/C19680001551}}
2. ^{{Cite journal| doi = 10.1021/ar950150s| volume = 29| issue = 7| pages = 348–354| last = Crabtree| first = Robert H.|author2=Siegbahn, Per E. M. |author3=Eisenstein, Odile |author4=Rheingold, Arnold L. |author5= Koetzle, Thomas F. | title = A New Intermolecular Interaction: Unconventional Hydrogen Bonds with Element−Hydride Bonds as Proton Acceptor| journal = Acc. Chem. Res.| date = 1996-01-01| pmid = 19904922}}
3. ^¹²{{Cite journal| doi = 10.1021/cr000021b| volume = 101| issue = 7| pages = 1963–1980| last = Custelcean| first = Radu|author2=Jackson, James E.| title = Dihydrogen Bonding: Structures, Energetics, and Dynamics| journal = Chem. Rev.| date = 2001-07-01| pmid = 11710237}}
4. ^Natalia V. Belkova, Elena S. Shubina, and Lina M. Epstein "Diverse World of Unconventional Hydrogen Bonds" Acc. Chem. Res., 2005, 38, 624–631. {{DOI|10.1021/ar040006j}}
5. ^{{Cite book| edition = 1| publisher = Springer| isbn = 0-306-46465-9| last = Kubas| first = Gregory J.| title = Metal Dihydrogen and -Bond Complexes - Structure, Theory, and Reactivity| date = 2001-08-31}}
6. ^{{Cite journal| doi = 10.1039/C3CC46048G| volume = 50| pages = 5212–5214| last = Yang| first = Lixu|author2=Hubbard, Thomas A. |author3=Cockroft, Scott L.| title = Can non-polar hydrogen atoms accept hydrogen bonds?| journal = Chem. Commun.| year = 2014| pmid = 24145311}}
7. ^Bakhmutov, Vladimir. I. Dihydrogen bonds: Principles, Experiments and Applications; John Wiley & Sons, Inc.: Hoboken, NJ, 2008. {{ISBN|9780470180969}}