In this work, we present a systematic theoretical study based on the density function theory (DFT), Through which we aim to shed light on the potential effects of dopped gold Au clusters with a platinum Pt atom, and the search for the new structural, chemical properties that gold clusters will have thanks to this doping, Where the study is limited to the selection of clusters with the lowest energy among the other isomers for each cluster size. The resulting stable structures with lower energy reveal three dimensional structures starting at n = 6, Doping Aun clusters with platinum Pt atom leads to improvement in all properties calculated for these clusters. The chemical and electronic properties have been studied and discussed, for example Vertical electronic affinity, adiabatic electronic affinity, enthalpy and chemical hardness as a function of cluster size. All properties were calculated using generalized gradient density approximation (GGA) and locus density approximation (LDA) and compared them with each other. Where it turns out that the results obtained are close to previous theoretical and experimental studies somewhat similar to them. This type of study is presented for the first time using the density function theory.
In the current paper, we present a systematic calculation based on the Density functional theory (DFT), which aims to highlight the potential effects of doping platinum Pt clusters and the new electronic and light structural characteristics of platinum-infused gold clusters Aun (n= 1-9), so that less energy clusters are selected from the rest of the isomers per cluster size. The most stable structures with the lowest 3D structures starting from n=6. The average length of the bonds between the atoms of each cluster and the binding energy of these clusters is calculated relative to their size. Structural characteristics were studied, discussed and compared with all calculated properties by Gradient Density Approximation (GGA) with the Local Density Approximation (LDA), also highlighted the intensity of calculated cases and comparison of Au2 cluster with PtAu that the grafting of Aun clusters platinum Pt, makes them have characteristics that distinguish them to be qualified in their use of chemical stimulation.
In this paper, we present a systematic computational study based on the density function theory (DFT), Which aims to shed light on the potential effects of doped gold Au clusters with a platinum Pt atom,and finding the new structural and electronic properties that will be enjoyed by gold doped with platinum PtAun (n = 1-9) clusters, So that the most stable clusters are selected from the rest of the isomers for each cluster size. We doped Aun clusters with Pt atom, we obtained very interesting results, Stable and most stable structures reveal three-dimensional structures starting from (n=6), Also, the results of the fragmentation energy and the second difference in binding energy of these clusters in relation to their size have been studied in depth. The electronic properties, such as the Homo-Lumo gap energy, Vertical ionization potential (VIP) and adiabatic ionization potential (AIP) as a function of cluster size are also studied and discussed. All properties calculated by the generalized gradient approximation (GGA) were compared with the results of the local density approximation (LDA). Whereas, the results showed that the Aun clusters doped with Pt atom changed significantly.
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