Effects of Temperature and Ionic Concentration on Nanodroplet Electrocoalescence

Chen, Qicheng; Ma, Jie; Zhang, Yingjin; Wu, Chuangui; Xu, Jinliang

doi:10.1021/acs.langmuir.8b03627

Cited by 13 publications

(7 citation statements)

References 32 publications

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“…Several studies have been conducted employing MD simulations to explore the behavior of a nanometer-sized droplet in presence of electric fields, which include studies on electrowetting, droplet condensation, evaporation, electrocoalescence , of droplets, and droplet breakup . One of the pioneering works in this field by Daub et al consisted of an MD simulation study of the electrowetting phenomenon at the nanoscale wherein a succinct description of the electrowetting behavior for nanodroplets considered the fact that the number of molecules at the surface is relatively high.…”

Section: Introductionmentioning

confidence: 99%

“…This calls for a comprehensive investigation in terms of different aspects that influence the wetting dynamics and statics of a nanoscale droplet in presence of electric field, and a number of these studies have utilized molecular dynamics (MD) simulations. 11,14,16,17 Several studies have been conducted employing MD simulations to explore the behavior of a nanometer-sized droplet in presence of electric fields, which include studies on electrowetting, 18 droplet condensation, 19 evaporation, 20 electrocoalescence 21,22 of droplets, and droplet breakup. 23 One of the pioneering works in this field by Daub et al 18 consisted of an MD simulation study of the electrowetting phenomenon at the nanoscale wherein a succinct description of the electrowetting behavior for nanodroplets considered the fact that the number of molecules at the surface is relatively high.…”

Section: Introductionmentioning

confidence: 99%

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Molecular Investigation of Contact Line Movement in Electrowetted Nanodroplets

2020

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Molecular dynamics (MD) simulation of an electrowetted nanodroplet is performed to understand the fundamental origin of the involved parameters resulted from the molecular movement in the vicinity of the three-phase contact line (TPCL). During the spreading of the droplet, contact line friction (CLF) force is found to be the controlling one among all other resistive forces. Being molecular in nature, MD study is required to unveil the CLF, which is manifested by the TPCL friction coefficient ζ. The combined effect of temperature, electric field, and surface wettability, manifested by the solid–liquid Lennard-Jones interaction parameter, is studied to explore the droplet spreading. The entire droplet wetting dynamics is divided into two different regimes, namely, spreading regime and equilibrium regime. The molecular frequency during the TPCL movement in the equilibrium regime is affected by the presence of any external perturbation and results in an alteration of ζ. The predetermined knowledge of the alteration of CLF due to the coupling effect of electric field and temperature will have a potential application towards designing electric field-inspired droplet movement devices.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Molecular Investigation of Contact Line Movement in Electrowetted Nanodroplets

2020

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“…Simulations on pure water droplet coalescence in the gas phase − or on a super-hydrophobic surface to examine the coalescence-induced jumping were carried out. , Recently, our group has just studied the thermodynamics and dynamics of coalescence of pure water droplets . In addition to the case of pure water droplets, MD simulation studies on the coalescence of metal nanodroplets − and electrocoalescence of conducting droplets − were also reported.…”

Section: Introductionmentioning

confidence: 99%

Free Energy and Dynamics of Organic-Coated Water Droplet Coalescence

Pak

Tse

2020

J. Phys. Chem. C

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Organic matter is prevalent in the atmosphere. How such organic matter affects droplet coalescence is a critical issue in atmospheric sciences. In this paper, we investigated the effects of three different organic coatings formed by benzoic acid, heptanoic acid, and pimelic acid on coalescence. We studied the thermodynamics of coalescence by calculating the free energy change and decomposed it into energetic ΔU and entropic TΔS contributions to understand the molecular details. ΔU was primarily determined by the flexibility of the organic compound, its solubility in water, and hydrogen bond networks. We found a strong positive correlation between TΔS and the mobility of water and organic molecules. To understand the dynamics of coalescence, we studied collisions between two organic-coated water droplets of the same size at various initial speeds, impact parameters, and collision angles and reported the critical speeds at which coalescence transitions to separation/shattering. We showed that when a collision of the droplets leads to shattering, an organic coating can influence the size distribution of particulate matter that has implications for air pollution. We also discovered that collisions of organic-coated droplets can often induce rotations.

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“…These hydrodynamic studies are very successful for understanding large droplets; however, for nanodroplets, molecular correlations and nanoscale interfacial effects become significant, the driving force is the specified molecular interaction, and the inhomogeneity of the fluids is at the molecular lever; in this case, macroscopic hydrodynamics is inapplicable. For nanoscale systems, molecular dynamics (MD) is one of the most popular methods . For example, Pothier et al used MD simulations to examine the coalescence of Cu and Si nanodroplets in three‐dimensional (3D), quasi‐two‐dimensional (quasi‐2D) and two‐dimensional (2D) spaces, respectively.…”

Section: Introductionmentioning

confidence: 99%

“…However, in 2D space, coalescence is dominated by the inertial regime only. Chen et al used MD simulations to investigate how temperature and ionic concentration affect the coalescence of two nanodroplets. Chen et al found that a higher ion concentration and a lower temperature increased the effective particle‐particle interaction but decreased the mobility of the solvent, which resulted in a favorable ion concentration and favorable temperature for coalescence of a nanodroplet.…”

Section: Introductionmentioning

confidence: 99%

Time‐dependent density functional study for nanodroplet coalescence

Niu

Liu

et al. 2019

AIChE Journal

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The coalescence of nanodroplets is an important interfacial phenomenon and is the key to many real-world applications. However, the microscopic mechanism for this process remains unclear. In this work, we propose a time-dependent density functional theory (TDDFT) to understand and predict this process. The formation of a "peanut" nanodroplet seems key to the coalescence process, before and after which the system is dominated by a nucleation mechanism and an ordinary diffusion mechanism, respectively. It appears that molecular attraction is not only the driving force but also the resistance of droplet coalescence. The velocity distribution indicates that there is a significant mass transfer on the vapor-liquid interphase. During coalescence, there is a clear linear correlation between the free energy and the surface area of the vapor-liquid interface, which means surface tension is the dominant contribution to the free energy.

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Effects of Temperature and Ionic Concentration on Nanodroplet Electrocoalescence

Cited by 13 publications

References 32 publications

Molecular Investigation of Contact Line Movement in Electrowetted Nanodroplets

Molecular Investigation of Contact Line Movement in Electrowetted Nanodroplets

Free Energy and Dynamics of Organic-Coated Water Droplet Coalescence

Time‐dependent density functional study for nanodroplet coalescence

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