Modeling approaches for atmospheric ion–dipole collisions: all-atom trajectory simulations and central field methods

Neefjes, Ivo; Halonen, Roope; Vehkamäki, Hanna; Reischl, Bernhard

doi:10.5194/acp-22-11155-2022

Cited by 7 publications

(8 citation statements)

References 59 publications

(64 reference statements)

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“…We have previously shown that the central field approach yields very similar results to those from sampling collision trajectories using MD, provided that the attractive interaction used in the central field model is fitted to the tail of the potential of mean force (PMF) between the collision partners (Neefjes et al, 2022). The largest collision partners studied in that study were, however, dimers.…”

Section: Introductionmentioning

confidence: 80%

“…Molecular dynamics (MD) simulations allow us to study the time evolution of collision systems, where all intra-and intermolecular interactions are described through force fields. Recently, we have developed several atomistic molecular dynamics simulation frameworks (Yang et al, 2018;Halonen et al, 2019;Neefjes et al, 2022) to determine collision probabilities from sampling trajectories of atoms or molecules, which predict enhanced collision rate coefficients in good agreement with experiments (Lehtipalo et al, 2016;Stolzenburg et al, 2020). However, as the adequate sampling of collision probabilities requires simulating a large number of binary collisions, these approaches are computationally expensive.…”

Section: Introductionmentioning

confidence: 88%

“…To calculate collision and sticking probabilities in atomistic molecular dynamics simulations we need simple, but robust, criteria for when two collision partners have collided and when they are sticking together, as the large number of individual trajectories makes a manual inspection unfeasible. Collision/sticking criteria can be based on geometric and/or energetic properties of the system (Yang et al, 2018;Halonen et al, 2019;Neefjes et al, 2022). Here, we considered a criterion based on the center of mass distance between the collision partners, as this does not require knowledge of the detailed bonding between monomers and clusters of different sizes and can be directly related to the analytical interacting hardsphere model.…”

Section: Collision and Sticking Criteriamentioning

confidence: 99%

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Collision-sticking rates of acid–base clusters in the gas phase determined from atomistic simulation and a novel analytical interacting hard-sphere model

Hui

Neefjes

Tikkanen

et al. 2023

Preprint

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Abstract. Kinetics of collision-sticking processes between vapor molecules and clusters of low volatile compounds govern the initial steps of atmospheric new particle formation. Conventional non-interacting hard-sphere models underestimate the collision rate by neglecting long-range attractive forces, and the commonly adopted assumption that every collision leads to the formation of a stable cluster (unit mass accommodation coefficient) is questionable for small clusters, especially at elevated temperatures. Here, we present a generally applicable analytical interacting hard-sphere model for evaluating collision rates between molecules and clusters, accounting for long-range attractive forces. In the model, the collision cross section is calculated based on an effective molecule-cluster potential, derived using Hamaker's approach. Applied to collisions of sulfuric acid or dimethylamine with neutral bisulphate-dimethylammonium clusters composed of 1–32 dimers, our new model predicts collision rates 2–3 times higher than the non-interacting model for small clusters, while decaying asymptotically to the non-interacting limit as cluster size increases, in excellent agreement with a collision rate theory-atomistic molecular dynamics simulation approach. Additionally, we calculated sticking rates and mass accommodation coefficients (MAC) using atomistic molecular dynamics collision simulations. For sulfuric acid, unit MAC is observed for collisions with all cluster sizes at temperatures between 200 K and 400 K. For dimethylamine, we find that MACs decrease with increasing temperature and decreasing cluster size. At low temperatures, the unit MAC assumption is generally valid, but at elevated temperatures MACs can drop below 0.2 for small clusters.

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Section: Introductionmentioning

confidence: 80%

Section: Introductionmentioning

confidence: 88%

Section: Collision and Sticking Criteriamentioning

confidence: 99%

See 1 more Smart Citation

Collision-sticking rates of acid–base clusters in the gas phase determined from atomistic simulation and a novel analytical interacting hard-sphere model

Hui

Neefjes

Tikkanen

et al. 2023

Preprint

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“… 67 This additional attractive potential between the ion and the neutral molecule increased the collision cross-sectional area and alter the angle of collision between the ion and neutral molecule. Furthermore, preliminary molecular dynamic simulations following Neefjes et al 68 suggest a higher collision rate constant for acetate ions (with and without water ligand) with sulfuric acid compared to nitrate dimer ion due in part to acetate’s dipole moment. A forthcoming molecular dynamic simulation study will examine the role ion’s dipole and composition play on collision rate constants with molecular dipoles.…”

Section: Resultsmentioning

confidence: 99%

Ion–Molecule Rate Constants for Reactions of Sulfuric Acid with Acetate and Nitrate Ions

et al. 2022

Self Cite

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Atmospheric nucleation from precursor gases is a significant source of cloud condensation nuclei in the troposphere and thus can affect the Earth’s radiative balance. Sulfuric acid, ammonia, and amines have been identified as key nucleation precursors in the atmosphere. Studies have also shown that atmospheric ions can react with sulfuric acid to form stable clusters in a process referred to as ion-induced nucleation (IIN). IIN follows similar reaction pathways as chemical ionization, which is used to detect and measure nucleation precursors via atmospheric pressure chemical ionization mass spectrometers. The rate at which ions form clusters depends on the ion–molecule rate constant. However, the rate constant varies based on the ion composition, which is often not known in the atmosphere. Previous studies have examined ion–molecule rate constants for sulfuric acid and nitrate ions but not for other atmospherically relevant ions like acetate. We report the relative rate constants of ion–molecule reactions between nitrate and acetate ions reacting with sulfuric acid. The ion–molecule rate constant for acetate and sulfuric acid is estimated to be a factor of 1.9–2.4 times higher than that of the known rate constant for nitrate and sulfuric acid. Using quantum chemistry, we find that acetate has a higher dipole moment and polarizability than nitrate. This may contribute to an increase in the collision cross-sectional area between acetate and sulfuric acid and lead to a greater reaction rate constant than nitrate. The ion–molecule rate constant for acetate with sulfuric acid will help quantify the contribution of acetate ions to atmospheric ion-induced new particle formation.

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“…In this study, we explore issues related to both obtaining and maintaining thermal equilibrium when performing MD simulations of bimolecular reactions in the gas phase, close to the free molecular regime. 32,33 We focus on simulations of flexible molecular compounds with explicit internal dof, i.e., vibrational modes. First, to study issues related to establishing thermal equilibrium and equipartitioning, we tested the often-used Nosé-Hoover, Canonical Sampling through Velocity Rescaling, and Langevin thermostats, using a system of 30 As the aim of this study is primarily methodological, the potential problems related to thermostatted simulations are investigated using a computationally inexpensive classical force field approach, rather than a chemically more realistic reactive force field or a quantum mechanical description of the compounds and their interactions.…”

Section: Introductionmentioning

confidence: 99%

Further cautionary tales on thermostatting in Molecular Dynamics: energy equipartitioning and non-equilibrium processes in gas-phase simulations

Halonen

Neefjes

Reischl

2023

Preprint

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Molecular dynamics (MD) simulations of gas-phase chemical reactions are typically carried out on a small number of molecules near thermal equilibrium by means of various thermostatting algorithms. Correct equipartitioning of kinetic energy among translations, rotations and vibrations of the simulated reactants is critical for many processes occurring in the gas phase. As thermalizing collisions are infrequent in gas-phase simulations, the thermostat has to efficiently reach equipartitioning in the system during equilibration and maintain it throughout the actual simulation. Furthermore, in non-equilibrium simulations where heat is released locally, the action of the thermostat should not lead to unphysical changes in the overall dynamics of the system. In this study, we explore issues related to both obtaining and maintaining thermal equilibrium in MD simulations of an exemplary ion-molecule dimerization reaction. We first compare the efficiency of Nosé-Hoover, Canonical Sampling through Velocity Rescaling, and Langevin thermostats for equilibrating the system and find that of these three only the Langevin thermostat achieves equipartition in a reasonable simulation time. We also study the effect of unphysical removal of latent heat released during simulations involving multiple dimerization events, when global thermostatting schemes are applied, which effectively cools down the reactants and leads to an overestimation of the dimerization rate. Our findings underscore the importance of thermostatting for the proper thermal initialization of gas-phase systems and the consequences of global thermostatting in non-equilibrium MD simulations.

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Modeling approaches for atmospheric ion–dipole collisions: all-atom trajectory simulations and central field methods

Cited by 7 publications

References 59 publications

Collision-sticking rates of acid–base clusters in the gas phase determined from atomistic simulation and a novel analytical interacting hard-sphere model

Collision-sticking rates of acid–base clusters in the gas phase determined from atomistic simulation and a novel analytical interacting hard-sphere model

Ion–Molecule Rate Constants for Reactions of Sulfuric Acid with Acetate and Nitrate Ions

Further cautionary tales on thermostatting in Molecular Dynamics: energy equipartitioning and non-equilibrium processes in gas-phase simulations

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