Application of Optimization Algorithms in Clusters

Srivastava, Ruby

doi:10.3389/fchem.2021.637286

Cited by 7 publications

(7 citation statements)

References 234 publications

(247 reference statements)

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“…[22] Even focusing on the study of the global optimization of metal nanoparticles and nanoalloys only, there has been intense research activity and much effort, because of the importance of these systems both in fundamental science and in practical applications. [23][24][25][26][27] Different methods have been recently developed to tackle the problem of global optimization: basin hopping [28] and evolutionary-based algorithms, [29][30][31][32][33][34][35][36][37] lattice Monte Carlo, [38] mirror-rotation optimization algorithms, [39] curvilinear coordinate, [40] biminima optimizations, [41,42] and particle swarm optimization. [43] Global optimization is a very challenging task already for one-component (elemental) nanoparticles due to the enormous number of local equilibrium configurations (i.e., of local minima) of the PES, which is expected to exponentially increase with the number of atoms N. [44][45][46] These local minima correspond to different geometric structures which in principle can present quite different properties.…”

Section: Introductionmentioning

confidence: 99%

Optimizing the Shape and Chemical Ordering of Nanoalloys with Specialized Walkers

Rapetti

Roncaglia

Ferrando

2023

Advcd Theory and Sims

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New algorithms for the optimization of alloy nanoparticles (nanoalloys) are presented. The new algorithms are based on the concept of multiple basin‐hopping walkers running in parallel, each with its own specialized task—the flying walker, exploring the energy landscape at high temperatures to sample different geometric structures, and the landing and hiking walkers mainly refining the optimization of chemical ordering at low temperatures. These algorithms are referred to as flying‐landing (FL) and flying‐landing‐hiking (FLH). The algorithms are tested against several benchmarks (AuCu and AuRh clusters of 400 atoms and PtNi clusters of 38 and 55 atoms). In all cases, both FL and FLH are shown to perform very well compared to previous results in the literature. In addition, the algorithms are applied to the optimization of larger AgCu nanoparticles, with sizes up to 4000 atoms, in order to establish the behavior of the mixing energy and to compare full global optimization of shape and chemical ordering with optimization of chemical ordering alone at a fixed shape. In general, the results show that the simultaneous optimization of shape and chemical ordering is necessary in many cases, and that the FLH approach is especially efficient for that purpose.

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Section: Introductionmentioning

confidence: 99%

Optimizing the Shape and Chemical Ordering of Nanoalloys with Specialized Walkers

Rapetti

Roncaglia

Ferrando

2023

Advcd Theory and Sims

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“…31 This article is licensed under CC-BY-NC-ND 4 Most gas-phase cluster algorithms usually contain two main steps: the first involves identifying local minima on the PES using low-cost energy calculations. There are a variety of methods for minima search on the PES, including genetic algorithms (GA), 8−13 Monte Carlo simulations (MC), 8,9 and molecular dynamics simulations (MD). 8,9 The second step is usually a geometry optimization of the low-lying isomers found on the PES using higher level scoring methods, such as quantum chemistry calculations.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Moreover, in the gas phase, in contrast to the solid state, the clusters are not limited by any known symmetry groups or sizes. Many different algorithms have been used to tackle the problem of clusters in the gas phase. − A well-known algorithm for periodic systems is the ab initio random structure searching (AIRSS) . The algorithm generates random “sensible” structures and then relaxes them into the closest minimum point using periodic DFT, possibly using symmetries to help to narrow down the search space.…”

Section: Introductionmentioning

confidence: 99%

Monte Carlo-Simulated Annealing and Machine Learning-Based Funneled Approach for Finding the Global Minimum Structure of Molecular Clusters

Roth,

Toker,

Major

2023

ACS Omega

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Understanding the physical underpinnings and geometry of molecular clusters is of great importance in many fields, ranging from studying the beginning of the universe to the formation of atmospheric particles. To this end, several approaches have been suggested, yet identifying the most stable cluster geometry (i.e., global potential energy minimum) remains a challenge, especially for highly symmetric clusters. Here, we suggest a new funneled Monte Carlo-based simulated annealing (SA) approach, which includes two key steps: generation of symmetrical clusters and classification of the clusters according to their geometry using machine learning (MCSA-ML). We demonstrate the merits of the MCSA-ML method in comparison to other approaches on several Lennard-Jones (LJ) clusters and four molecular clustersSer8(Cl–)2, H+(H2O)6, Ag+(CO2)8, and Bet4Cl–. For the latter of these clusters, the correct structure is unknown, and hence, we compare the experimental and simulated fragmentation patterns, and the fragmentation of the proposed global minimum matches experiments closely. Additionally, based on the fragmentation of the predicted betaine cluster, we were able to identify hitherto unknown neutral fragmentation channels. In comparison to results obtained with other methods, we demonstrated a superior ability of MCSA-ML to predict clusters with high symmetry and similar abilities to predict clusters with asymmetrical structures.

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“…Various experimental techniques such as laser ablation coupled with mass spectrometry, photoelectron spectroscopy have been employed to get insights into the atomic clusters. Along with experimental studies, theoretical investigations are required to get a better understanding of their geometric arrangement and corresponding properties (Srivastava, 2021).…”

Section: Introductionmentioning

confidence: 99%

Atomic Clusters: Structure, Reactivity, Bonding, and Dynamics

2021

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Atomic clusters lie somewhere in between isolated atoms and extended solids with distinctly different reactivity patterns. They are known to be useful as catalysts facilitating several reactions of industrial importance. Various machine learning based techniques have been adopted in generating their global minimum energy structures. Bond-stretch isomerism, aromatic stabilization, Rener-Teller effect, improved superhalogen/superalkali properties, and electride characteristics are some of the hallmarks of these clusters. Different all-metal and nonmetal clusters exhibit a variety of aromatic characteristics. Some of these clusters are dynamically stable as exemplified through their fluxional behavior. Several of these cluster cavitands are found to be agents for effective confinement. The confined media cause drastic changes in bonding, reactivity, and other properties, for example, bonding between two noble gas atoms, and remarkable acceleration in the rate of a chemical reaction under confinement. They have potential to be good hydrogen storage materials and also to activate small molecules for various purposes. Many atomic clusters show exceptional opto-electronic, magnetic, and nonlinear optical properties. In this Review article, we intend to highlight all these aspects.

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Application of Optimization Algorithms in Clusters

Cited by 7 publications

References 234 publications

Optimizing the Shape and Chemical Ordering of Nanoalloys with Specialized Walkers

Optimizing the Shape and Chemical Ordering of Nanoalloys with Specialized Walkers

Monte Carlo-Simulated Annealing and Machine Learning-Based Funneled Approach for Finding the Global Minimum Structure of Molecular Clusters

Atomic Clusters: Structure, Reactivity, Bonding, and Dynamics

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