Your search keyword '"Cao, Qianqian"' showing total 17 results

1. Effects of Contact Behavior and Electric Field on Electrohydrodynamics of Nanodroplets

Author

Pan, Xuanzuo, Cao, Qianqian, Liu, Dandan, and Wu, Zhenyu

Published

2022

2. Electroosmotic flow in a nanofluidic channel coated with neutral polymers

Author

Cao, Qianqian, Zuo, Chuncheng, Li, Lujuan, Ma, Yanhong, and Li, Nan

Published

2010

3. Effects of confinement geometry on shape transition and interfacial behavior of nanodroplets in externally applied electric field.

Author

Li, Lujuan, Cao, Qianqian, Yang, Kaijun, Lyu, Yixuan, Chen, Hongli, You, Hao, and Lyu, Yong

Subjects

*ELECTRIC fields, *MOLECULAR dynamics, *MOLECULAR interactions, *MOLECULAR shapes, *GEOMETRY

Abstract

The electric field-induced shape transition of a nanodroplet confined in a silicon nanogroove with variable structure was investigated through molecular dynamics simulations. Our work provides insight into the relationship between the shape transition and the molecular interaction. We demonstrated that the geometric structure of the groove significantly influences the responsive behaviors of the droplet to the electric field. The simulations elucidate increasing the tilt angle of the groove reduces the critical field strength for the shape transition of the droplet under parallel electric field. Above the critical field, the droplet detaches from the groove and forms a liquid bridge across the groove, leading to weakened interfacial interactions. The detachment process of the droplet from the rectangular groove, which originates from the spreading of water molecules on perpendicular side walls, is different from the droplet initially confined in the groove with tilt angle higher than 90°. Under the perpendicular electric field, the droplet undergoes various shape transitions depending on the groove structure. In particular, the droplet in the groove with a moderate opening forms two asymmetrical liquid columns. The retraction behavior of the droplet in the groove with the small opening sheds light on the competition between interfacial interactions. The shape transition of droplets in the electric field due to the change of confinement nanostructures, such as liquid bridge, asymmetrical extension, branching and merging, is helpful to enrich the understanding of electrowetting and confinement dynamics of the droplets. [Display omitted] • A liquid bridge forms across the groove above critical parallel electric field. • The droplet in rectangular groove undergoes asymmetrical detachment process. • Geometric confinement influences orientational polarization of water molecules. • The droplet shows branching and merging shape under perpendicular electric field. [ABSTRACT FROM AUTHOR]

Published

2024

4. Molecular dynamics study of electrocoalescence of pure water and salty nanodroplets

Author

Cao Qianqian, Hao Liu, Xin Qiao, and Lujuan Li

Subjects

Coalescence (physics), Materials science, Diffusion, Ionic bonding, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Critical value, 01 natural sciences, Atomic and Molecular Physics, and Optics, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, Ion, Physics::Fluid Dynamics, Molecular dynamics, Chemical physics, Electric field, Physics::Atomic and Molecular Clusters, Materials Chemistry, Physical and Theoretical Chemistry, 0210 nano-technology, Critical field, Spectroscopy

Abstract

The mechanisms governing the electrocoalescence between droplets are intricate owing to the presence of many influential parameters. In this work, we conduct molecular dynamics simulations to explore the effects of electric field strength and ionic concentration on the electrocoalescence behaviors of one pure water droplet and one salty droplet. The dynamic evolution is difierent from that for two identical droplets. The electric field strengths are chosen near the critical value. When the electric field strength is less than the critical value, the coalescence process is similar regardless of the ionic concentration of the salty droplet. The analysis on the mobility of ions demonstrates that the diffusion time of ions is much longer compared to the characteristic time of deformation of the coalesced droplet. At a stronger electric field than the critical field, the coalescence behavior exhibits dependence on the ionic concentration. For cases of high ionic concentrations, a rebounding behavior between two droplets is identified due to aggregation of ions close to the contact region of the droplets. Further, we also investigate molecular interaction energy, hydrogen bonding and ejection of daughter droplets during the electrocoalescence. Our study reveals that the coupling effect between the electric field and the ionic concentration plays an important role in controlling the electrocoalescence behavior of droplets.

Published

2021

5. Insights into the hydrogen-bond cross-linking effects of small multiamine molecules on physical and mechanical properties of poly(vinly alcohol) by molecular dynamics simulations.

Author

Li, Lujuan, Xu, Xiaodong, Song, Pingan, Cao, Qianqian, Qiao, Xin, Xu, Zhiguang, Yang, Yang, Zuo, Chuncheng, and Wang, Hao

Subjects

MOLECULAR dynamics, SMALL molecules, POLYVINYL alcohol, GLASS transition temperature, HYDROGEN bonding interactions, HYDROGEN bonding

Abstract

Small organic multiamine and multihydroxyl molecules have great potential for enhancing overall properties of poly(vinyl alcohol) (PVA) through the cross-linking effect of hydrogen bonds. However, experimentally there remains a remarkable lack of insightful understanding of the cross-linking effect on a molecular level. In the work, we report molecular dynamics simulations to reveal the cross-linking effect of hydrogen bonds of tetraaminopyrimidine (4N-2456) molecules on the structure, chain dynamics and mechanical properties of the PVA matrix. It was found that the addition of 4N-2456 leads to a nonlinear decrease of the free volume of PVA. A critical concentration of 4N-2456, about 5 wt%, was identified, resulting in the formation of 4N-2456 clusters. At this concentration, the PVA chains show the relatively slow mobility, the higher glass transition temperature and elastic modulus. Further increasing the 4N-2456 concentration enhances aggregation, and conversely weakens the interactions of hydrogen bonds between the PVA chains. Our work offers an understanding of how the 4N-2456 molecules influence the PVA chain dynamics and mechanical properties of the PVA matrix on molecular level. [ABSTRACT FROM AUTHOR]

Published

2021

6. Mechanisms of electric field-induced interactions between nanodroplets transmitted through a graphene monolayer.

Author

Li, Lujuan, Cao, Qianqian, and Liu, Dandan

Subjects

*MONOMOLECULAR films, *ELECTRIC field effects, *MOLECULAR dynamics, *ELECTROSTATIC interaction, *ELECTRIC fields, *GRAPHENE, *ELECTROSTATIC fields

Abstract

This study examines molecular interactions between two nanodroplets locating on the graphene monolayer and their morphological transition under the electric field parallel to the monolayer surface by using molecular dynamics simulations. The effects of the electric field and the salt concentration on the transmitted interactions, droplet shape and microscopic structure of interfacial water are elucidated in detail. It was found that the electric field can boost the electrostatic interaction between two pure water (PW) droplets, but weaken the short-range LJ interaction. The electric field with low strength mainly causes separation of two droplets rather than changes their shapes. There is a faster response of microscopic structures of water molecules to strong electric field than the morphological change of droplets, leading to a transition of the interaction energy from strong to weak. The salt concentration in the salty water (SW) droplets has negligible effect on the interaction energy in the absence of electric field. At strong electric field, the break-up behaviors of the SW droplets depend on the salt concentration. Simulation results reveal that the transmitted interactions between the PW and SW droplets as well as two SW droplets significantly affect the break-up behaviors and morphological transition of the droplets. • Electric field boosts electrostatic interaction between two pure water droplets. • Transmitted short-range interaction through the graphene monolayer is negligible in the presence of electric field. • Break-up behaviors of salty water droplets depend on salt concentration and transmitted interactions. [ABSTRACT FROM AUTHOR]

Published

2023

7. Anomalous electrokinetics at hydrophobic surfaces: Effects of ion specificity and interfacial water structure.

Author

Cao, Qianqian and Netz, Roland R.

Subjects

*ELECTROKINETICS, *HYDROPHOBIC surfaces, *INTERFACES (Physical sciences), *HYDROPHOBIC interactions, *MOLECULAR dynamics

Abstract

We study the electrokinetic transport behavior of water molecules and ions in hydrophobic graphene nanochannels with variable surface charge densities as well as the interfacial water structure based on detailed molecular dynamics simulations. The interfacial water structure, described by the water density, hydrogen bonding, diffusion, distribution of the OH bond and dipole orientations, is strikingly influenced by the surface charge sign and density. We find anomalous electrokinetic effects which are related to the distribution of counterions close to the surface, ion-specific effects and the interfacial water structure. On a negatively charged graphene layer, the attraction of Na + ions towards the surface enhances the interfacial friction. In contrast, if the surface is positively charged, high surface charge density triggers an anomalous enhancement of electroosmotic flow, accompanied by an abrupt change of the interfacial water structure. At high surface charge densities, the mobility of the interfacial water at the positively charged surfaces is suppressed more strongly compared to the negatively charged surface. Our results reveal new electrokinetic phenomena by the comparison of negatively and positively charged surfaces. [ABSTRACT FROM AUTHOR]

Published

2018

8. Electrohydrodynamics of spherical polyampholyte-grafted nanoparticles: Multiscale simulations by coupling of molecular dynamics and lattice-boltzmann method.

Author

Cao, Qianqian, Li, Lujuan, and Zuo, Chuncheng

Subjects

*ELECTROHYDRODYNAMICS, *POLYAMPHOLYTES, *NANOPARTICLES, *MOLECULAR dynamics, *LATTICE Boltzmann methods

Abstract

ABSTRACT We perform multiscale simulations based on the coupling of molecular dynamics and lattice-Boltzmann (LB) method to study the electrohydrodynamics of a polyampholyte-grafted spherical nanoparticle. The long-range hydrodynamic interactions are modeled by coupling the movement of particles to a LB fluid. Our results indicate that the net-neutral soft particle moves with a nonzero mobility under applied electric fields. We systematically explore the effects of different parameters, including the chain length, grafting density, electric field, and charge sequence, on the structures of the polymer layer and the electrophoretic mobility of the soft particle. It shows that the mobility of nanoparticles has remarkable dependence on these parameters. We find that the deformation of the polyampholyte chains and the ion distribution play dominant roles in modulating the electrokinetic behavior of the polyampholyte-grafted particle. The enhancement or reduction in the accumulation of counterions around monomers can be attributed to the polymer layer structure and the conformational transition of the chains in the electric field. © 2017 Wiley Periodicals, Inc. J. Polym. Sci., Part B: Polym. Phys. 2017, 55, 1435-1447 [ABSTRACT FROM AUTHOR]

Published

2017

9. Morphologies of spherical polyampholyte brushes: Effects of counterion valence and charged monomer sequence.

Author

Cao, Qianqian and You, Hao

Subjects

*POLYAMPHOLYTES, *MONOMERS, *MOLECULAR dynamics, *ELECTROSTATICS, *STIFFNESS (Mechanics)

Abstract

We study the conformational behavior of spherical brushes composed of polyampholyte chains end-grafted onto spherical particles in the presence of monovalent and tetravalent counterions using molecular dynamics simulations. The overall net charge for each chain consisting of both positively and negatively charged segments is zero. The dependences of the structural properties of the brushes on the chain stiffness, grafting density and charge sequence along the chains are examined systemically. For the diblock brushes, our results indicate that increasing the chain rigidity leads to a significant effect of counterion valence and a reduced collapsing degree of the brushes. At high chain stiffness, the number of high-valent counterions trapped in the brushes is diminished compared to the cases with monovalent counterions, corresponding to lower osmotic pressure. For the flexible brushes, the short-range and electrostatic interactions depending on the charge sequence, determine the conformational transition of the brushes, whereas the effect of counterion valence becomes weaker. In the presence of high-valent counterions, the brushes which consist of polyampholyte chains with blocks of medium length, adopt a slightly stretched conformation owing to relatively strong electrostatic correlation between high-valent counterions and oppositely charged monomers. [ABSTRACT FROM AUTHOR]

Published

2017

10. Impact of surface charge density and motor force upon polyelectrolyte packaging in viral capsids.

Author

Cao, Qianqian and Bachmann, Michael

Subjects

*POLYELECTROLYTES, *CAPSIDS, *CHARGE density waves, *MOLECULAR dynamics, *LANGEVIN equations

Abstract

ABSTRACT By means of Langevin molecular dynamics simulations, we study the packaging dynamics of flexible and semiflexible polyelectrolytes in spherical cavities that resemble viral capsids. We employ a coarse-grained model of the polymer-capsid complex that allows us to perform simulations of a 900mer and investigate the influence of surface charges inside the capsid and an additional motor force, acting on the polymer in the portal region of the cavity, on the packaging process. Our results indicate that it is most efficient if surface charges are present that initially promote the formation of an ordered surface layer inside the capsid. Once these charges are screened, the motor force pulls in the remaining part of the chain. Additionally, the simulations also demonstrate that the packaging dynamics depends on the counterion valence. © 2016 Wiley Periodicals, Inc. J. Polym. Sci., Part B: Polym. Phys. 2016, 54, 1054-1065 [ABSTRACT FROM AUTHOR]

Published

2016

11. Interaction and dynamics of two nanodroplets separated by monolayer graphene.

Author

Li, Lujuan and Cao, Qianqian

Subjects

*MONOMOLECULAR films, *VAN der Waals forces, *MOLECULAR dynamics, *GRAPHENE, *ELECTRIC fields, *MOLECULAR interactions, *DIPOLE-dipole interactions

Abstract

• Transmission of molecular interactions through graphene can drive migration of droplets. • Enhancing electric field accelerates migration velocity of two droplets towards each other. • Dipole–dipole interactions of interfacial water enhance deflection of water dipoles. • Critical electric field to induce large deformation becomes lower for cases of two droplets. Understanding the physical mechanism of wetting transparency of monolayer graphene, or how atoms or molecules located on opposite sides of the atomically thin carbon monolayer transmit molecular interactions (such as van der Waals and electrostatic forces) is of significant importance for many extraordinary applications from scientific and practical perspectives. In the current work, we carried out molecular dynamics simulations to explore the interactions between two droplets (TD) separated by the monolayer graphene under applied electric field. The results indicate that in the absence of the electric field the transmission of molecular interactions can drive migration of two droplets towards each other, implying partial wetting transparency of the graphene. Compared to the cases of single droplet (SD), the critical electric field to induce large deformation is lower for the TD cases. However, the droplet–droplet interactions under strong electric fields suppress the reduction of the number of water molecules in the graphene/droplet interface and the elongation of droplets. To understand the enhancement of interactions between two droplets owing to the electric field, we analyze microscopic structures of interfacial water (dipole orientation distribution and hydrogen bonding). The dipole–dipole interaction through the graphene mainly contributes to the droplet–droplet interactions. It was found that significant deflection of water dipoles for the TD cases occurs as the electric field enhances, but the deflection for the SD cases is smaller and even the droplet is detached from the graphene surface. Our findings provide fundamental insights on the influence of the electric field on molecular interactions between two droplets through the monolayer graphene and clues for developing potential graphene-based nanofluidic applications controlled by external electric field. [ABSTRACT FROM AUTHOR]

Published

2022

12. Charged Nanoparticle Transport in Polymer-Grafted Nanochannels.

Author

Sun, He, Ma, Siliang, Yuan, Yuan, and Cao, Qianqian

Subjects

NANOPARTICLES, POLYMERS, MOLECULAR dynamics, ELECTRIC fields, ELECTROKINETICS, MONOMERS, NONLINEAR analysis

Abstract

Molecular dynamics simulations were used to investigate the electric field-induced migration of nanoparticles in a nanochannel grafted with a polymer brush. The distribution of nanoparticles, brush monomer density and migration velocity are addressed at different electric field strengths and grafting densities. The increase of the grafting density leads to a decrease of the effective radius of the nanochannel. At high grafting density, the distribution of nanoparticles is shifted significantly towards the center of the channel. Enhancing the electric field leads to a very slight change of brush monomer density. The migration velocity increases with the electric field rapidly at weak electric fields, while a slow increase is observed at strong electric fields. Additionally, it is found that the migration velocity of nanoparticles exhibits a nonlinear dependence on the grafting density. [ABSTRACT FROM PUBLISHER]

Published

2013

13. Electrophoresis of Bottle-Brush Polyelectrolytes in an Attractive Nanochannel.

Author

Cao, Qianqian, Zuo, Chuncheng, Li, Lujuan, and Zhang, Yinhe

Abstract

A molecular dynamics study of the electrophoresis of bottle-brush polyelectrolytes (BPEs) through nanochannels is reported. The BPE molecules consist of a neutral backbone with charged side chains. For strong attractive interactions between the BPE and the wall, the BPE is being trapped on the channel surface. A stretching-shrinking migration of the BPE in a channel of radius 6 σ is observed at relatively strong electric fields. The stretching-shrinking transition is periodic for intermediate electric fields but not for stronger electric fields. The BPE also shows a transverse migration toward the wall at weak electric fields, while toward the center with further enhancing the electric field. For a channel with larger radius 12 σ, the BPE does not migrate in the stretching-shrinking manner. [ABSTRACT FROM AUTHOR]

Published

2012

14. Electro-osmotic flow in nanochannels with voltage-controlled polyelectrolyte brushes: Dependence on grafting density and normal electric field.

Author

Cao, Qianqian, Zuo, Chuncheng, Li, Lujuan, Zhang, Yinhe, and Yan, Guang

Subjects

*POLYELECTROLYTES, *MOLECULAR dynamics, *ELECTRO-osmosis, *ELECTRIC fields, *FLOW velocity, *FLUID flow

Abstract

Molecular dynamics simulations were performed for electro-osmotic flow (EOF) confined in a polyelectrolyte-grafted nanochannel under variable grafting density and normal electric field. With decreasing the value of the normal electric field, the brush undergoes a collapse transition, and the ion distribution is changed significantly. The brush thickness increases on increasing the grafting density at positive and weak negative electric fields, whereas a reduced brush thickness is observed at strong negative electric field. Our results further reveal that the flow velocity is not only dependent on conformational transition of the brush but also related to the cation and anion distributions. At low grafting density, the EOF is almost completely quenched at high electric field strength due to strong surface friction between ions and walls. For the case of very dense grafting, the flow velocity is influenced weakly within the brush when varying the grafting density. Additionally, a bidirectional flow occurs at an intermediate electric field. The investigation on fluid flux indicates that the fluid flux is insensitive to the grafting density, when the normal electric field is removed. For nonzero normal electric fields, a significant change in the fluid flux is observed at low grafting densities. © 2012 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys, 2012 [ABSTRACT FROM AUTHOR]

Published

2012

15. Hybrid Particle–Continuum Simulations of Polymer Brushes in Shear Flow.

Author

Cao, Qianqian, Zuo, Chuncheng, and Li, Lujuan

Subjects

*SHEAR flow, *PARTICLES, *POLYMERS, *MATHEMATICAL continuum, *SURFACE coatings, *MOLECULAR dynamics, *NAVIER-Stokes equations

Abstract

A hybrid particle–continuum method is used to study the shear flow confined between two opposing walls, one of which is coated with polymer chains. Molecular dynamics (MD) is used in the particle region near the brush and Navier–Stokes (NS) equations are applied in the remaining region where the continuum assumption holds. The information exchange from the continuum region to the particle region is implemented using the constrained particle dynamics. Both Couette shear flow and oscillatory flow are considered in the present work. The effect of the shear flow on the conformational characteristics of polymer brushes is analyzed. In the overlap region, the velocities obtained from MD simulations are smoothly connected with those from NS equations. Our investigations demonstrate that the hybrid particle–continuum model is valid in exploring the shear behavior of polymer brushes. [ABSTRACT FROM AUTHOR]

Published

2012

16. Effects of chain stiffness and salt concentration on responses of polyelectrolyte brushes under external electric field.

Author

Cao, Qianqian, Zuo, Chuncheng, Li, Lujuan, and Yan, Guang

Subjects

*STIFFNESS (Mechanics), *SALT, *MOLECULAR dynamics, *POLYELECTROLYTES, *ELECTRIC fields, *SIMULATION methods & models, *CONFORMATIONAL analysis

Abstract

We report a molecular dynamics study on non-equilibrium dynamics of polyelectrolyte brushes under external electric fields. In this work, the effects of chain stiffness and salt concentration on static and dynamic responses of the brushes are addressed in detail. Our simulations indicate that varying these parameters induce rich electro-responsive behavior of the brushes. The increase of salt concentration results in the enhancement of an opposite electric field formed by non-equilibrium distribution of cations and anions, which resists stretching or shrinkage of grafted chains. At strong positive electric fields, the flexible brushes are more sensitive to the change of salt concentration. When reversing the electric field, the stiff brushes undergo a conformational transition from collapse to complete stretching. At high salt concentrations, dynamic responsive magnitude of the brush thickness to added electric field is strongly reduced. It was found that the fall time for the stiff brush becomes much shorter than that for the flexible brush. Additionally, increasing ion concentration leads to an excess extension or shrinkage of flexible brushes. For strongly stiff brushes, such phenomenon occurs in the presence or absence of salt. [ABSTRACT FROM AUTHOR]

Published

2011

17. Molecular dynamics study of electrocoalescence of pure water and salty nanodroplets.

Author

Li, Lujuan, Cao, Qianqian, Liu, Hao, and Qiao, Xin

Subjects

*ELECTRIC field effects, *MOLECULAR dynamics, *ELECTRIC fields, *IONIC mobility, *MOLECULAR interactions, *ION mobility

Abstract

The mechanisms governing the electrocoalescence between droplets are intricate owing to the presence of many influential parameters. In this work, we conduct molecular dynamics simulations to explore the effects of electric field strength and ionic concentration on the electrocoalescence behaviors of one pure water droplet and one salty droplet. The dynamic evolution is difierent from that for two identical droplets. The electric field strengths are chosen near the critical value. When the electric field strength is less than the critical value, the coalescence process is similar regardless of the ionic concentration of the salty droplet. The analysis on the mobility of ions demonstrates that the diffusion time of ions is much longer compared to the characteristic time of deformation of the coalesced droplet. At a stronger electric field than the critical field, the coalescence behavior exhibits dependence on the ionic concentration. For cases of high ionic concentrations, a rebounding behavior between two droplets is identified due to aggregation of ions close to the contact region of the droplets. Further, we also investigate molecular interaction energy, hydrogen bonding and ejection of daughter droplets during the electrocoalescence. Our study reveals that the coupling effect between the electric field and the ionic concentration plays an important role in controlling the electrocoalescence behavior of droplets. • Mechanisms of electrocoalescence between pure water and salty droplets are explored. • Coupling effect between electric field and ionic concentration plays a critical role. • Remarkable inconsistency between ion diffusion and droplet deformation is identified. [ABSTRACT FROM AUTHOR]

Published

2021