Data_Sheet_1_A Global Optimizer for Nanoclusters.PDF
We have developed an algorithm to automatically build the global minimum and other low-energy minima of nanoclusters. This method is implemented in PyAR (https://github.com/anooplab/pyar) program. The global optimization in PyAR involves two parts, generation of several trial geometries and gradient-based local optimization of the trial geometries. While generating the trial geometries, a Tabu list is used for storing the information of the already used trial geometries to avoid using the similar trial geometries. In this recursive algorithm, an n-sized cluster is built from the geometries of n−1 clusters. The overall procedure automatically generates many unique minimum energy geometries of clusters with size from 2 up to n using this evolutionary growth strategy. We have used our strategy on some of the well-studied clusters such as Pd, Pt, Au, and Al homometallic clusters, Ru-Pt and Au-Pt binary clusters, and Ag-Au-Pt ternary cluster. We have analyzed some of the popular parameters to characterize the clusters, such as relative energy, singlet-triplet energy difference, binding energy, second-order energy difference, and mixing energy, and compared with the reported properties.
History
Usage metrics
Categories
- Geochemistry
- Biochemistry
- Organic Chemistry
- Medical Biochemistry: Proteins and Peptides (incl. Medical Proteomics)
- Nuclear Chemistry
- Medical Biochemistry and Metabolomics not elsewhere classified
- Analytical Biochemistry
- Cell Neurochemistry
- Physical Organic Chemistry
- Enzymes
- Organic Green Chemistry
- Environmental Chemistry (incl. Atmospheric Chemistry)
- Catalysis and Mechanisms of Reactions
- Electroanalytical Chemistry
- Analytical Chemistry not elsewhere classified
- Environmental Chemistry
- Food Chemistry and Molecular Gastronomy (excl. Wine)
- Inorganic Chemistry