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Hauptverfasser: Bredice, Mitchell, Rozman, Michael G., Smucker, Jonathan, Farmer, Eric, Côté, Robin, Kharchenko, Vasili
Format: Preprint
Veröffentlicht: 2023
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Online-Zugang:https://arxiv.org/abs/2303.12918
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author Bredice, Mitchell
Rozman, Michael G.
Smucker, Jonathan
Farmer, Eric
Côté, Robin
Kharchenko, Vasili
author_facet Bredice, Mitchell
Rozman, Michael G.
Smucker, Jonathan
Farmer, Eric
Côté, Robin
Kharchenko, Vasili
contents In this study, molecular dynamics simulations were conducted to investigate the relaxation of the internal energy in nano-sized particles and its impact on the nucleation of atomic clusters. Quantum-mechanical potentials were utilized to analyze the growth and collision relaxation of the internal energy of Ar$_n$H$^+$ clusters in a metastable Ar gas. The results revealed that small nano-clusters are formed in highly excited rotational-vibrational states, and the relaxation of internal energy and growth of these nascent clusters are concurrent processes with a strong mutual influence. Under non-equilibrium growth conditions, the relaxation of internal energy can delay the cluster growth process. The rates of cluster growth and internal energy relaxation were found to be influenced by energy-transfer collisions between cluster particles and free Ar atoms of the bath gas. Furthermore, the non-equilibrium growth and internal energy relaxation of small nano-clusters were found to depend on the structure of the cluster's atomic shells. An ensemble of molecular dynamics simulations were conducted to investigate the growth, time-evolution of kinetic and total energies of Ar$_n$H$^+$ clusters with specified $n \leq 11$, and the results were explained by collisional relaxation processes described by the Boltzmann equation. Finally, the general relationship between the rates of internal energy relaxation and non-equilibrium growth of nano-particles is discussed.
format Preprint
id arxiv_https___arxiv_org_abs_2303_12918
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Inner Energy Relaxation and Growth of Nano-Size Particles
Bredice, Mitchell
Rozman, Michael G.
Smucker, Jonathan
Farmer, Eric
Côté, Robin
Kharchenko, Vasili
Atomic and Molecular Clusters
In this study, molecular dynamics simulations were conducted to investigate the relaxation of the internal energy in nano-sized particles and its impact on the nucleation of atomic clusters. Quantum-mechanical potentials were utilized to analyze the growth and collision relaxation of the internal energy of Ar$_n$H$^+$ clusters in a metastable Ar gas. The results revealed that small nano-clusters are formed in highly excited rotational-vibrational states, and the relaxation of internal energy and growth of these nascent clusters are concurrent processes with a strong mutual influence. Under non-equilibrium growth conditions, the relaxation of internal energy can delay the cluster growth process. The rates of cluster growth and internal energy relaxation were found to be influenced by energy-transfer collisions between cluster particles and free Ar atoms of the bath gas. Furthermore, the non-equilibrium growth and internal energy relaxation of small nano-clusters were found to depend on the structure of the cluster's atomic shells. An ensemble of molecular dynamics simulations were conducted to investigate the growth, time-evolution of kinetic and total energies of Ar$_n$H$^+$ clusters with specified $n \leq 11$, and the results were explained by collisional relaxation processes described by the Boltzmann equation. Finally, the general relationship between the rates of internal energy relaxation and non-equilibrium growth of nano-particles is discussed.
title Inner Energy Relaxation and Growth of Nano-Size Particles
topic Atomic and Molecular Clusters
url https://arxiv.org/abs/2303.12918