Aurophilicity

When the ligand on the left is treated with 3 equivalents of a gold(I) halide (with each phosphine group coordinating a separate gold center), the aurophilic interaction between gold atoms hinders free rotation around single bonds. The temperature required to restore free rotation on the NMR timescale is a measure of the strength of the aurophilic interaction.[1]

In chemistry, aurophilicity refers to the tendency of gold complexes to aggregate via formation of weak gold-gold bonds.[1][2]

The main evidence for aurophilicity is from the crystallographic analysis of Au(I) complexes. The aurophilic bond is assigned a length of about 3.0 Å and a strength of about 7–12 kcal/mol,[1] which is comparable to the strength of a hydrogen bond. The aurophilic interaction is thought to result from electron correlation of the closed-shell components, which is unusual because closed-shell atoms generally have negligible interaction with one another at distances on the scale of the Au-Au bond. This is somewhat similar to van der Waals interactions, but is unusually strong due to relativistic effects. Observations and theory show that, on average, 28% of the binding energy in aurophilic interaction can be attributed to relativistic expansion of the gold d orbitals.[3]

An example of aurophilicity is the propensity of gold centres to aggregate. While both intra- and inter-molecular aurophilic interactions have been observed, only intramolecular aggregation has been observed at such nucleation sites.[4]

Role in self-assembly

The similarity in strength between hydrogen bonding and aurophilic interaction has proven to be a convenient tool in the field of polymer chemistry. Much research has been conducted on self-assembling supermolecular structures, both those that aggregate by aurophilicity alone and those that contain both aurophilic and hydrogen-bonding interactions.[5] An important and exploitable property of aurophilic interactions relevant to their supermolecular chemistry is that while both inter- and intramolecular interactions are possible, intermolecular aurophilic linkages are comparatively weak and easily broken by solvation; most complexes that exhibit intramolecular aurophilic interactions retain such moieties in solution.[1]

Gold(I) complexes can polymerize by intermolecular aurophilic interaction. Nanoparticles that form from this polymerization often give rise to intense luminescence in the visible region of the spectrum. Strength of particular intermolecular aurophilic interactions can be gauged by solvating the nanoparticles and observing the extent to which luminescence diminishes.[1]

Similar metallophilic interactions exist for other heavy metals, such as mercury and palladium, and can also be observed between atoms of different elements. Examples include Pd(II)-Pd(I),Pt(II)-Pd(I),[6] Hg(II)-Au(I), Hg(II)-Pt(II), and Hg(II)-Pd(II).[7] In accordance with theoretical calculations, which predict a local maximum for relevant relativistic effects for gold atoms, none of these other interactions are as strong as aurophilicity.[1][8] Although metallophilic interactions are not inherently relativistic in their nature, they are complemented by it.

References

  1. 1 2 3 4 5 6 Hubert Schmidbaur (2000). "The Aurophilicity Phenomenon: A Decade of Experimental Findings, Theoretical Concepts and Emerging Application". Gold Bulletin. 33 (1): 3–10. doi:10.1007/BF03215477.
  2. Hubert Schmidbaur (1995). "Ludwig Mond Lecture. High-carat gold compounds". Chem. Soc. Rev. 24 (6): 391–400. doi:10.1039/CS9952400391.
  3. Nino Runeberg; Martin Schütz & Hans-Joachim Werner (1999). "The aurophilic attraction as interpreted by local correlation methods". J. Chem. Phys. 110 (15): 7210–7215. Bibcode:1999JChPh.110.7210R. doi:10.1063/1.478665.
  4. Hubert Schmidbaur; Stephanie Cronje; Bratislav Djordjevic & Oliver Schuster (2005). "Understanding gold chemistry through relativity". J. Chem. Phys. 311: 151–161. Bibcode:2005CP....311..151S. doi:10.1016/j.chemphys.2004.09.023.
  5. William J. Hunks; Michael C. Jennings & Richard J. Puddephatt (2002). "Supramolecular Gold(I) Thiobarbiturate Chemistry: Combining Aurophilicity and Hydrogen Bonding to Make Polymers, Sheets, and Networks". Inorg. Chem. 41 (17): 4590–4598. doi:10.1021/ic020178h.
  6. Yin, Xi; Warren, Steven A.; Pan, Yung-Tin; Tsao, Kai-Chieh; Gray, Danielle L.; Bertke, Jeffery; Yang, Hong (15 December 2014). "A Motif for Infinite Metal Atom Wires". Angewandte Chemie International Edition. 53 (51): 14087–14091. doi:10.1002/anie.201408461.
  7. Kim Mieock; Taylor Thomas J.; Gabbai François P. (2008). "Hg(II)···Pd(II) Metallophilic Interactions". J. Am. Chem. Soc. 130 (20): 6332–6333. doi:10.1021/ja801626c. PMID 18433123.
  8. Behnam Assadollahzadeh & Peter Schwerdtfege (2008). "A comparison of metallophilic interactions in group 11[X–M–PH3]n (n = 2–3) complex halides (M = Cu, Ag, Au; X = Cl, Br, I) from density functional theory". Chemical Physics Letters. 462 (4–6): 222–228. Bibcode:2008CPL...462..222A. doi:10.1016/j.cplett.2008.07.096.
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