Abstract
N-heterocyclic carbenes (NHCs) are versatile ligands in organometallic chemistry, prized for their strong σ-donating and tunable electronic properties. They are used to stabilize a wide range of motifs, including clusters and nanoparticles, based in particular on coinage metals—Cu, Ag, and Au. Notably, the carbene 13C NMR isotropic chemical shift (δiso) of NHC-coinage metal complexes varies significantly across these elements, reflecting the nuanced interplay of electronic and structural factors. Here, we study the carbene carbon chemical shift in NHC-Au(I)-X complexes (X = H, OH, halides, CN, N3 and neutral ligands such as pyridine and NHC) compared to the Cu and Ag congeners. Density functional theory (DFT) calculations are used to analyze the chemical shielding tensor (CST) components, revealing that stronger σ‐donor X‐ligands lead to greater deshielding of δiso through enhanced paramagnetic contributions and, for Au, spin–orbit contributions of comparable magnitude. Moreover, a correlation between the spin-orbit contribution to the chemical shift (σso) and the Au-carbene bond distance highlights the critical role of trans-influence in modulating spin-orbit coupling and the overall chemical shift. Analysis of σso shows that stronger σ-donor ligands, associated with a greater trans-influence and elongated Au-carbene bond, lead to a higher-lying NHC-Au σ-bond and lower-lying π*-bond, ultimately yielding greater deshielding and higher 13C chemical shift. This work provides insight into how structural and electronic factors govern carbene chemical shifts in NHC-based Au complexes and clusters, establishing a direct link between NMR spectroscopic descriptor and electronic structure, thus opening avenues for developing structure-activity relationships in catalysis and materials science.
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Optimized structures
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