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Ranking the efficiency of gas hydrate anti agglomerants through molecular dynamic simulations

Using both computational and experimental methods, the capacity of four different surfactant molecules to inhibit the agglomeration of sII hydrate particles was assessed. The computational simulations were carried out using both steered and non-steered Molecular Dynamics (MD), simulating the coalescence process of a hydrate slab and a water droplet, both covered with surfactant molecules. The experimental work was based on rocking cell measurements, determining the minimum effective dose necessary to inhibit agglomeration. Overall, good agreement was obtained between the performance predicted by the simulations and the experimental measurements. Moreover, the simulations allowed to gain additional insights that are not directly accessible via experiments, such as an analysis of the mass density profiles, the diffusion coefficients, or the orientations of the long tails.

preprint2021arXivOpen access
Stephan MohrFelix HoevelmannJonathan WyldeNatascha ScheleroJuan SarriaNirupam PurkayasthaZachary WardPablo Navarro AceroVasileios K. Michalis
physics.chem-ph
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Open access9 authors1 topic
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Stephan MohrFelix HoevelmannJonathan WyldeNatascha ScheleroJuan SarriaNirupam PurkayasthaZachary WardPablo Navarro AceroVasileios K. Michalis

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