Emergent Properties of Antiagglomerant Films Control Methane Transport: Implications for Hydrate Management

Sicard, François; Bui, Tai; Monteiro, Deepak; Liu, Qiang; Ceglio, Mark; Burress, Charlotte; Striolo, Alberto

doi:10.1021/acs.langmuir.8b01366

Cited by 32 publications

(60 citation statements)

References 133 publications

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“…To quantify synergistic or antagonistic effects, we monitored changes in the structure of the AAs within the interfacial film due to the presence of aromatics. It should be noted that the order of the interfacial film was found to be correlated with the AAs performance, as well as with the ability of methane to diffuse from the hydrocarbon phase to the hydrate substrate in our prior studies 8,27 . To quantify the order of the AAs films, we calculated the deuterium order parameter, S CD , for carbon atoms in the long alkyl tails of the AAs.…”

Section: Number Of N-dodecane Moleculesmentioning

confidence: 59%

“…1a. To construct the initial configurations, we followed the procedure described in our previous study 27 . Each simulated system contains a sII methane hydrate substrate of size 5.193 × 5.193 × 3.462 nm.…”

Section: Simulation Methodologymentioning

confidence: 99%

“…7, right panel, is drilled within the hydrate substrate. However, building on arguments that relate emulsions stability to interfacial mechanic barriers or the film strength as measured by interfacial elasticity 62,63 , ordered and rigid interfacial films should yield strong repulsion between the two approaching hydrates 8,27 .…”

Section: Number Of N-dodecane Moleculesmentioning

confidence: 99%

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Synergistic and Antagonistic Effects of Aromatics on the Agglomeration of Gas Hydrates

Bui

Monteiro

et al. 2020

Sci Rep

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Surfactants are often used to stabilize aqueous dispersions. For example, surfactants can be used to prevent hydrate particles from forming large plugs that can clog, and sometimes rupture pipelines. Changes in oil composition, however dramatically affect the performance of said surfactants. In this work we demonstrate that aromatic compounds, dissolved in the hydrocarbon phase, can have both synergistic and antagonistic effects, depending on their molecular structure, with respect to surfactants developed to prevent hydrate agglomerations. While monocyclic aromatics such as benzene were found to disrupt the structure of surfactant films at low surfactant density, they are expelled from the interfacial film at high surfactant density. On the other hand, polycyclic aromatics, in particular pyrene, are found to induce order and stabilize the surfactant films both at low and high surfactant density. Based on our simulation results, polycyclic aromatics could behave as natural anti-agglomerants and enhance the performance of the specific surfactants considered here, while monocyclic aromatics could, in some cases, negatively affect performance. Although limited to the conditions chosen for the present simulations, the results, explained in terms of molecular features, could be valuable for better understanding synergistic and antagonistic effects relevant for stabilizing aqueous dispersions used in diverse applications, ranging from foodstuff to processing of nanomaterials and advanced manufacturing. Dispersions are found in a variety of applications, from foodstuff to minerals processing, from biotechnology to nanotechnology, from 3D printing to advanced manufacturing. One relevant application in the energy sector concerns flow assurance. In oil and gas pipelines, the simultaneous presence of natural gas and water can lead to the formation of hydrate plugs, which could clog, and sometimes rupture the pipeline. In addition, gas hydrates can form in many offshore energy processes 1. The unintended formation of hydrate plugs can cause disruptions in oil and gas production, as well as large negative environmental consequences 1-3. Among other approaches to manage gas hydrates is the stabilization of hydrate particles in hydrocarbon dispersions. Specifically designed surfactants, known as anti-agglomerants (AAs), are optimized to prevent hydrate plug formation in flow assurance 4,5. AAs are believed to adsorb on hydrate particles by their hydrophilic head groups, while the AAs tail groups are soluble in the hydrocarbon phase. The hydrate particles, as well as water droplets, are expected to be covered by a film of AAs and oil, making them repel each other and disperse 5-9. This rich system offers an ideal platform to test our fundamental understanding regarding the stabilization of dispersions using surfactants. In fact, laboratory and field observations alike show that many phenomena determine the AAs' performance. Small changes in the molecular structure of the surfactants, changes in salt content, and in gas/oil and i...

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Section: Number Of N-dodecane Moleculesmentioning

confidence: 59%

Section: Simulation Methodologymentioning

confidence: 99%

Section: Number Of N-dodecane Moleculesmentioning

confidence: 99%

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Synergistic and Antagonistic Effects of Aromatics on the Agglomeration of Gas Hydrates

Bui

Monteiro

et al. 2020

Sci Rep

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“…184 Some hydrocarbon chains were found to penetrate the AAs film, in qualitative agreement with experimental data by Tokiwa et al 185 These results also provide a new hypothesis for the mechanism by which AAs function: when the AAs form an ordered film, they could prevent methane transport across the interface. 186…”

Section: Some Advancements In the Understanding Of Clathrate Hydratesmentioning

confidence: 99%

Clathrate hydrates: recent advances on CH₄ and CO₂ hydrates, and possible new frontiers

Striolo

2019

Molecular Physics

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Gas hydrates continue to attract enormous attention throughout the energy industry, as both a hindrance in conventional production and a substantial unconventional resource. Scientists continue to be fascinated by hydrates because of their peculiar properties, including the ability of sequestering large amounts of hydrophobic gases, unusual thermal transport properties, and unique molecular structures. From a technological point of view, clathrate hydrates offer potential advantages in applications as diverse as natural gas production, carbon sequestration, water desalination and natural gas storage. The communities interested in hydrates span traditional academic disciplines, including earth science, physical chemistry, and petroleum engineering. The studies on this field are equally diverse, including field expeditions to attempt the production of natural gas from hydrate deposits accumulated naturally on the seafloor, to lab-scale studies to attempt to exchange CO2 for the CH4 present in hydrate deposits; from the scale up of water desalination plants to the testing of compounds used to prevent the formation of large hydrate plugs in pipelines; from theoretical studies to understand the stability of hydrates depending on the guest molecules, to molecular simulations to probe nucleation mechanisms. This review highlights a few fundamental questions faced by the research community, with focus on knowledge gaps representing some of the barriers that must be addressed to enable growth in the practical applications of hydrate technology, including natural gas storage, water desalination, CO2-CH4 exchange in hydrate deposits, and prevention of hydrate plugs in conventional energy transportation.

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“…Because the density of methane within such interfacial films was negligible, Bui et al [47] suggested that the AAs they considered could prevent hydrate plug formation, in part, causing an interfacial barrier that prevent both water and methane from reaching the hydrate particle. Sicard et al [48] quantified the strong free energy barrier encountered by methane when it travels across such interfaces. For these calculations, enhanced sampling techniques including metadynamics, umbrella sampling, and adiabatic biased MD were implemented.…”

Section: Recent Simulationsmentioning

confidence: 99%

Molecular properties of interfaces relevant for clathrate hydrate agglomeration

Striolo

Phan

Walsh

2019

Current Opinion in Chemical Engineering

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Clathrate hydrates of natural gases show promise for energy in regions traditionally poor of fossil fuels, suggest the possibility of mitigating the atmospheric impact of hydrocarbon consumption via CO2 sequestration, could advance high-tech applications to address global challenges, including the water-energy nexus, and can lead to significant economic loss and potential safety hazards when they form in oil and gas pipelines. This focused review is motivated by several recent contributions, which demonstrate how atomistic and coarsegrained simulations have become a useful tool. The examples provided suggest the time is right to take advantage of the enhanced understanding provided by simulations, to couple them with experiments that could help design new chemicals for managing hydrate formation in pipelines, for designing chemical processes and additives to advance high-tech applications such as water desalination and natural gas storage, and perhaps also for the production of methane from geological hydrate deposits with simultaneous carbon dioxide sequestration.

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Emergent Properties of Antiagglomerant Films Control Methane Transport: Implications for Hydrate Management

Cited by 32 publications

References 133 publications

Synergistic and Antagonistic Effects of Aromatics on the Agglomeration of Gas Hydrates

Synergistic and Antagonistic Effects of Aromatics on the Agglomeration of Gas Hydrates

Clathrate hydrates: recent advances on CH₄ and CO₂ hydrates, and possible new frontiers

Molecular properties of interfaces relevant for clathrate hydrate agglomeration

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Emergent Properties of Antiagglomerant Films Control Methane Transport: Implications for Hydrate Management

Cited by 32 publications

References 133 publications

Synergistic and Antagonistic Effects of Aromatics on the Agglomeration of Gas Hydrates

Synergistic and Antagonistic Effects of Aromatics on the Agglomeration of Gas Hydrates

Clathrate hydrates: recent advances on CH4 and CO2 hydrates, and possible new frontiers

Molecular properties of interfaces relevant for clathrate hydrate agglomeration

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Product

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Clathrate hydrates: recent advances on CH₄ and CO₂ hydrates, and possible new frontiers