Density-functional tight-binding for phosphine-stabilized nanoscale gold clusters

Abstract: We report a parameterization of the density-functional tight-binding (DFTB) method for the accurate prediction of molecular, electronic and vibrational structure of phosphine-ligated nanoscale gold clusters, metalloids, and gold surfaces.

“…Reproduced with permission. [ 328 ] Copyright 2020, Royal Society of Chemistry. c) Calculated SO‐TDDFT UV−vis absorption spectra of the [Au 9 (PPh 3 ) 8 ] 3+ cluster in both DCM and MeOH.…”

“…[334] Following the development of the DFTB parameters for Au-P interactions, the simulations of ground-state properties such as IR and Raman spectra of very large phosphine-stabilized clusters can be made 1000× faster than before. Figure 15b shows the optimized geometry of Au 108 S 24 (PPh 3 ) 16 and the predicted far-IR spectra calculated using the DFTB2/auorg 𝛼' developed by Vuong et al [328]…”

“…[ 274 ] Recently, tight‐binding parameters for the Au–P interactions were generated and tested. [ 328 ] One of the applied benchmarks was the analysis of ligand bond dissociation of [Au 8 (PPh 3 ) 8 ] 2+ compared with DFT ( Figure 15 a ). This work demonstrated that using these parameters in DFTB formalism, ligand removal energy pathways can be calculated with computational ease for any phosphine‐stabilized Au cluster that is commonly de‐ligated for catalytic applications.…”

“…Figure 15b shows the optimized geometry of Au 108 S 24 (PPh 3 ) 16 and the predicted far‐IR spectra calculated using the DFTB2/auorg α ’ developed by Vuong et al. [ 328 ]…”

“…The recent development of the density functional tight‐binding parameters for the Au–P interaction has paved the way for faster calculation of ground‐state properties such as geometric and electronic structures and energetics, alongside the simulation of infrared spectra for phosphine‐stabilized Au clusters. [ 328 ] The accelerated calculation of the optical properties of these nanoclusters using time‐dependent DFTB could soon be the standard as the simulated absorption spectra of the large Au 70 S 20 (PPh 3 ) 12 and Au 108 S 24 (PPh 3 ) 16 clusters have recently been reported. [ 346 ] Likewise, the development of tight‐binding parameters involving the interaction of Au and P with different substrate surfaces like titania is necessary to further improve material design and reaction tunability of cluster‐based heterogeneous catalysts.…”

A Review of State of the Art in Phosphine Ligated Gold Clusters and Application in Catalysis

“…Reproduced with permission. [ 328 ] Copyright 2020, Royal Society of Chemistry. c) Calculated SO‐TDDFT UV−vis absorption spectra of the [Au 9 (PPh 3 ) 8 ] 3+ cluster in both DCM and MeOH.…”

“…[334] Following the development of the DFTB parameters for Au-P interactions, the simulations of ground-state properties such as IR and Raman spectra of very large phosphine-stabilized clusters can be made 1000× faster than before. Figure 15b shows the optimized geometry of Au 108 S 24 (PPh 3 ) 16 and the predicted far-IR spectra calculated using the DFTB2/auorg 𝛼' developed by Vuong et al [328]…”

“…[ 274 ] Recently, tight‐binding parameters for the Au–P interactions were generated and tested. [ 328 ] One of the applied benchmarks was the analysis of ligand bond dissociation of [Au 8 (PPh 3 ) 8 ] 2+ compared with DFT ( Figure 15 a ). This work demonstrated that using these parameters in DFTB formalism, ligand removal energy pathways can be calculated with computational ease for any phosphine‐stabilized Au cluster that is commonly de‐ligated for catalytic applications.…”

“…Figure 15b shows the optimized geometry of Au 108 S 24 (PPh 3 ) 16 and the predicted far‐IR spectra calculated using the DFTB2/auorg α ’ developed by Vuong et al. [ 328 ]…”

“…The recent development of the density functional tight‐binding parameters for the Au–P interaction has paved the way for faster calculation of ground‐state properties such as geometric and electronic structures and energetics, alongside the simulation of infrared spectra for phosphine‐stabilized Au clusters. [ 328 ] The accelerated calculation of the optical properties of these nanoclusters using time‐dependent DFTB could soon be the standard as the simulated absorption spectra of the large Au 70 S 20 (PPh 3 ) 12 and Au 108 S 24 (PPh 3 ) 16 clusters have recently been reported. [ 346 ] Likewise, the development of tight‐binding parameters involving the interaction of Au and P with different substrate surfaces like titania is necessary to further improve material design and reaction tunability of cluster‐based heterogeneous catalysts.…”

A Review of State of the Art in Phosphine Ligated Gold Clusters and Application in Catalysis

Recent Advances in Ligand Engineering for Gold Nanocluster Catalysis: Ligand Library, Ligand Effects and Strategies

Computational Modeling of 4d and 5d Transition Metal Catalysts