Full Molecular Dynamics Research Articles

Molecular dynamics simulations on the adsorption of 4-n-octyl-4′-cyanobiphenyl (8CB) at the air/water interface

ABSTRACTThe influence of surface coverage to the structural properties of 4-n-octyl-4´-cyanobiphenyl (8CB) monolayer at the air/water interface was studied by full atomistic molecular dynamics simulations. These properties include density profiles, interface thickness, monolayer width, orientational order parameters, and atom-pair radial distribution functions. The calculated tilt angles of the cyanobiphenyl and alkyl parts are in fairly good agreement with the experiments. The simulation results exhibit the general trends in the previous experimental and simulation data.

Multiscale simulation of dynamic wetting

A sequential multiscale strategy that combines molecular dynamics (MD) with volume of fluid (VOF) simulations is proposed to study the spreading of droplets on surfaces. In this hybrid MD/VOF approach, VOF is applied everywhere in the domain with MD pre-simulations distributed along the wetted interface providing the crucial boundary information for the three-phase contact-line dynamics and the solid/liquid interfacial slip. For the latter, molecular shear flow simulations of the liquid in contact with the substrate are used to measure the local slip length to calibrate the Navier slip model. For the contact-line we use MD simulations of nanodroplets spreading on the substrate to calibrate the molecular kinetic theory (MKT) model for both the dynamic contact angle and the slip velocity. We validate this multiscale model for water nanodroplets spreading over a platinum surface by comparing our sequential hybrid simulations with the equivalent dynamics in a full MD treatment. We demonstrate that for nanodroplets spreading on surfaces, applying a dynamic contact angle model is not sufficient to pick up the molecular effects; we need to account for slip across the entire solid/liquid interface, in particular the large slip behaviour at the contact-line. We also demonstrate the application of this multiscale method to larger nanodroplets (up to ∼100nm diameters), where full MD simulation would be computationally intractable. We find that as the droplet size increases, the slip in the contact line region becomes less important. To simulate the full range of nano to macro droplets, an improved way of dealing with the VOF method is needed to reduce the overall number of grid points.

Hydrogen bonding and vibrational energy relaxation of interfacial water: A full DFT molecular dynamics simulation.

The air-water interface has been a subject of extensive theoretical and experimental studies due to its ubiquity in nature and its importance as a model system for aqueous hydrophobic interfaces. We report on the structure and vibrational energy transfer dynamics of this interfacial water system studied with equilibrium and non-equilibrium molecular dynamics simulations employing a density functional theory -based description of the system and the kinetic energy spectral density analysis. The interfacial water molecules are found to make fewer and weaker hydrogen (H)-bonds on average compared to those in the bulk. We also find that (i) the H-bonded OH groups conjugate to the free OH exhibit rather low vibrational frequencies (3000-3500 cm-1); (ii) the presence of a significant fraction (>10%) of free and randomly oriented water molecules at the interface ("labile water"), neither of whose OH groups are strong H-bond donors; (iii) the inertial rotation of free OH groups, especially from the labile water, contribute to the population decay of excited free OH groups with comparable rate and magnitude as intramolecular energy transfer between the OH groups. These results suggest that the labile water, which might not be easily detectable by the conventional vibrational sum frequency generation method, plays an important role in the surface water dynamics.

Effects of density on flow in a nano channel using a molecular-continuum hybrid method

A molecular-continuum hybrid method was developed to simulate micro- and nano-scale fluid flows that cannot be predicted using continuum fluidics. Molecular dynamics simulation was used near stationary solid surfaces, and Navier-Stokes equations were used in other regions. We carried out Couette flow simulation using this hybrid method and validated the results by comparing them with the analytical solution. We also studied the dependence of the velocity slip and slip length on the surface energy, liquid density, and roughness for a liquid channel flow with and without nano-structures on the solid surface. The behavior of the liquid near the solid wall changed with the surface energy as well as the liquid density. The variation of the velocity slip and slip length according to the surface energy also depended on the liquid density as well as the surface roughness. We compared the required computational time obtained from the molecular-continuum hybrid method with that obtained from full molecular dynamics simulation under the same computational condition, giving much shorter computational time for the case using the molecular-continuum hybrid method than that for full molecular dynamics simulation.

Tests for, origins of, and corrections to non-Gaussian statistics. The dipole-flip model.

Linear response approximations are central to our understanding and simulations of nonequilibrium statistical mechanics. Despite the success of these approaches in predicting nonequilibrium dynamics, open questions remain. Laird and Thompson [J. Chem. Phys. 126, 211104 (2007)] previously formalized, in the context of solvation dynamics, the connection between the static linear-response approximation and the assumption of Gaussian statistics. The Gaussian statistics perspective is useful in understanding why linear response approximations are still accurate for perturbations much larger than thermal energies. In this paper, we use this approach to address three outstanding issues in the context of the "dipole-flip" model, which is known to exhibit nonlinear response. First, we demonstrate how non-Gaussian statistics can be predicted from purely equilibrium molecular dynamics (MD) simulations (i.e., without resort to a full nonequilibrium MD as is the current practice). Second, we show that the Gaussian statistics approximation may also be used to identify the physical origins of nonlinear response residing in a small number of coordinates. Third, we explore an approach for correcting the Gaussian statistics approximation for nonlinear response effects using the same equilibrium simulation. The results are discussed in the context of several other examples of nonlinear responses throughout the literature.

Green’s function molecular dynamics: including finite heights, shear, and body fields

The Green’s function molecular dynamics (GFMD) method for the simulation of incompressible solids under normal loading is extended in several ways: shear is added to the GFMD continuum formulation and Poisson numbers as well as the heights of the deformed body can now be chosen at will. In addition, we give the full stress tensor inside the deformed body. We validate our generalizations by comparing our analytical and GFMD results to calculations based on the finite-element method (FEM) and full molecular dynamics simulations. For the investigated systems we observe a significant speed-up of GFMD compared to FEM. While calculation and proof of concept were conducted in two-dimensions only, the methodology can be extended to the three-dimensional case in a straightforward fashion.

Mechanical properties, electronic structure and alkali-ion diffusion of Eldfellite-type AFe(SO4)2 (A = Li, Na, K) as potential cathode materials comparing with LiFePO4

To elucidate the structure-performance relationship of the new potential cathode materials AFe(SO4)2 ([Formula: see text], Na, K) compared with LiFePO4, first-principles calculations are performed to investigate the structure, mechanical stabilities and electronic properties of them. The calculated results show that AFe(SO[Formula: see text] ([Formula: see text], Na, K) compounds are mechanically stable and exhibit strong anisotropy. LiFe(SO[Formula: see text], NaFe(SO[Formula: see text] and KFe(SO[Formula: see text] are more brittle and have higher elastic modulus than LiFePO4, which is attributed to the strong chemical bonding of them. Electronic structure are predicted by HSE06 functional and the band gaps are 5.006, 4.996, 5.146 and 3.711[Formula: see text]eV for LiFe(SO[Formula: see text], NaFe(SO[Formula: see text], KFe(SO[Formula: see text] and LiFePO4, respectively. Full ab initio molecular dynamics simulations are performed to calculate the mean square displacements and diffusion coefficients of the alkali-ion. NaFe(SO[Formula: see text] has large diffusion coefficient as [Formula: see text][Formula: see text]m2/s at 1273[Formula: see text]K, as well as larger activation energy as 0.167[Formula: see text]eV. All the results contribute to understand the microscopic origin of the different behaviors of intercalation cathode used in rechargeable battery.

Atomistic-continuum hybrid simulations for compressible gas flow in a parallel nanochannel

An atomistic-continuum hybrid method is proposed to simulate the compressible gas flow in nanochannel. Based on the domain decomposition method, the computational region is divided into two parts: the atomistic part and the continuum part. In the region near the wall, the molecular dynamics (MD) simulation is used; in the bulk region, finite volume method (FVM) is employed, which also provides necessary information for constructing inlet and outlet boundary conditions of atomistic part. After some validation of the hybrid code, it is used to study the Poiseuille flow in nano-scale channel. Pressures at the inlet and outlet boundaries are both generated as expected, and the pressure gradient is induced along the channel. The velocity and pressure profiles from the hybrid method agree well with full MD simulation. The variations of slip velocity and dimensionless slip length with Knudsen number are also studied, and a linear equation between dimensionless slip length and Knudsen number is obtained.

Thermal conductivity of 1D carbyne chains

Carbyne is a one-dimensional monoatomistic chain of carbon atoms, consisting of repeating sp-hybridized groups – the extreme minimalist molecular rod or chain. Due to their potential use in atomic-scale circuits, there has been particular interest in their novel electronic and thermal properties and are promising platforms for heat dissipation. Potential 1D thermal transport is advantageous as the heat conduction can theoretically be directed along the molecule. However, the thermal properties of carbyne, essential to their successful application in the design of novel devices, have yet to be rigorously determined. Here, using full atomistic molecular dynamics (MD), we explore the thermal conductivity (κ) of a system of carbyne chains to enable statistical averaging. Müller-Plathe reverse perturbation method was used to obtain κ along the chain direction. For a freestanding chain with a length of approximately 40nm, we indicate an ultrahigh thermal conductivity of approximately 0.793kW/m-K, on the similar order of carbon nanotubes and graphene. Also, when we look into the thermal conductivity by atomistic weight, the carbyne model we use obtains a higher value than (5, 5) CNT and is comparable to graphene nanoribbon, which indicates very promising thermal conduction. Moreover, chains of varying length and strain are simulated individually to systematically explore the accessible range of conductivities. The thermal conductivity decreases when more strain applied, while it is significantly enhanced when we add more atoms to the carbyne chains. Additionally, we reported a close-to-linear relationship between κ and chain length, which provided supportive evidence for the controlling of thermal conductivity of carbyne.

Sparse fulleryne structures enhance potential hydrogen storage and mobility

We propose a novel fullerene-like molecule—a so-called fulleryne—to increase potential hydrogen storage capacity of carbon-based systems, assessed via full atomistic molecular dynamics.

Design and mesoscopic description of self-propelled nanomotor in complex environment

Self-propulsion of micron and nanoscale objects in the low Reynolds number regime are commonly observed in biological systems. Micron and nanoscale synthetic self-propelled objects have been fabricated recently and the mechanisms that underlie their operation have been described. Researches about such motors are the interesting topic because of their potential applications as vehicles for drug delivery, cargo transport, motion-based bio-sensing, nanoscale assembly, targeted synthesis, nano- and microfluidics, etc. One type of such motors based on phoretic self-propulsion exhibit various dynamical phenomena that have attracted increasing attentions in the front interdiscipline fields of soft condensed matter, statistical physics, and nanotechnology. Studies on designing interesting nano-motor that can execute special tasks and exploration of their dynamics behavior in complex active matter have been more attractive recently. In this review, we introduce the mesoscopic dynamical scheme that is based on a coarse-grain description of molecular collisions-multiple particles collision dynamics (MPC). There are several attractive features of such a mesoscopic description. Due to simple dynamics, it is both easy and efficient to simulate. The equations of motion are easily written and the techniques of nonequilibriun statistical mechanics can be used to derive macroscopic laws and correlation function expressions for the transport properties. One can derive accurate analytical expressions for the transport coefficient. Especially, the mesoscopic description can be combined with full molecular dynamics in order to describe the properties of solute species, such as motor or colloids, in solution. Since all of the physical conservation laws are satisfied, hydrodynamic interactions, which play an important role in the dynamical properties of such systems, are automatically taken into account without additional assumption. This method can be combined with full molecular dynamics (MD) to construct a hybrid MPC-MD method. Furthermore, the reaction in solution can be taken into account, which extends the method as reactive multiple particles dynamics (RMPC). Therefore, the mesoscopic method can be utilized to simulate complex systems. In these examples, the motors move by selfphoresis, where the gradient of some field across the motor, which is generated by asymmetrical activity. It induces fluid flow in the surrounding medium resulting in propulsion. The phoretic propulsion mechanisms include self-electrophoresis, self-diffusiophoresis and selfthermophoresis. Here, we describe the basic theory for phoretic propulsion mechanisms. Then, we briefly review the process of simulation on self-propelled motor in recent years. Especially, we introduce the results in designing motor with different dynamics by means of MPC. For example, an asymmetric gear with homogeneous surface properties is presented as a prototype to fabricate catalytic microrotors. Lastly, we introduce the dynamical properties of sphere dimer motors, composed of linked catalytic and non-catalytic monomers, in active media. Synthetic chemically powered nanomotors often rely on the environment for their fuel supply. The propulsion properties of such motors can be altered if the environment they move is chemically active. Two examples are presented. The chemotactic properties of a sphere dimer motor are studied in a gradient field of fuel. We also consider how a sphere dimer motor moves in a chemically active medium and interacts with a chemical wave. It is found that a chemical wave can reflect a dimer motor, which suggests that the effect can provide a possible mechanism for the control of nanomotor motion in a patterned chemical system. Our investigation provides an introduction to the broader issue of self-propulsion in active media and suggests the possibility of a new class of applications and control scenarios.

FEM analysis of metal matrix nanocomposites reinforced with off-line atomistically-informed equivalent nanofillers

With ever increasing the applications of metal matrix nanocomposites (MMNCs) reinforced with carbon nanofillers, demand for accurate and effective modeling techniques in this area has been increased in recent years. To provide such a route, this study is dedicated to apply information form interfacial atomic interactions in modified continuum models implemented to analyze the mechanical behavior of these nanocomposites. In the proposed methodology, the metal matrix is considered as a continuous medium. Meanwhile, to capture the atomic-scale phenomena governing the problem, the carbon nanofiller, local metal atoms neighboring it, and the nanofiller/metal interface are analyzed using molecular dynamics (MD) simulations. Subsequently, employing the equivalent continuum modeling (ECM) concept, geometrical and mechanical characteristics of the equivalent nanofiller is obtained in each case and introduced in a finite element analysis (FEA). It is demonstrated that the atomistically informed FEA can successfully reproduce the results of full atomistic MD simulations with ignorable run-time compared to that of this method. Finally, constructing several computational cells with different metal matrices and reinforcing agents, the developed MD/FE multiscale approach is utilized to capture the influences of temperature, nanofiller geometry and orientation, its volume fraction and interfacial interactions on the axial elastic constants of these nanocomposites.

Kunitz-Type Peptide HCRG21 from the Sea Anemone Heteractis crispa Is a Full Antagonist of the TRPV1 Receptor.

Sea anemone venoms comprise multifarious peptides modulating biological targets such as ion channels or receptors. The sequence of a new Kunitz-type peptide, HCRG21, belonging to the Heteractis crispa RG (HCRG) peptide subfamily was deduced on the basis of the gene sequence obtained from the Heteractis crispa cDNA. HCRG21 shares high structural homology with Kunitz-type peptides APHC1–APHC3 from H. crispa, and clusters with the peptides from so named “analgesic cluster” of the HCGS peptide subfamily but forms a separate branch on the NJ-phylogenetic tree. Three unique point substitutions at the N-terminus of the molecule, Arg1, Gly2, and Ser5, distinguish HCRG21 from other peptides of this cluster. The trypsin inhibitory activity of recombinant HCRG21 (rHCRG21) was comparable with the activity of peptides from the same cluster. Inhibition constants for trypsin and α-chymotrypsin were 1.0 × 10−7 and 7.0 × 10−7 M, respectively. Electrophysiological experiments revealed that rHCRG21 inhibits 95% of the capsaicin-induced current through transient receptor potential family member vanilloid 1 (TRPV1) and has a half-maximal inhibitory concentration of 6.9 ± 0.4 μM. Moreover, rHCRG21 is the first full peptide TRPV1 inhibitor, although displaying lower affinity for its receptor in comparison with other known ligands. Macromolecular docking and full atom Molecular Dynamics (MD) simulations of the rHCRG21–TRPV1 complex allow hypothesizing the existence of two feasible, intra- and extracellular, molecular mechanisms of blocking. These data provide valuable insights in the structural and functional relationships and pharmacological potential of bifunctional Kunitz-type peptides.

Multiresolution molecular mechanics: Implementation and efficiency

Atomistic/continuum coupling methods combine accurate atomistic methods and efficient continuum methods to simulate the behavior of highly ordered crystalline systems. Coupled methods utilize the advantages of both approaches to simulate systems at a lower computational cost, while retaining the accuracy associated with atomistic methods. Many concurrent atomistic/continuum coupling methods have been proposed in the past; however, their true computational efficiency has not been demonstrated. The present work presents an efficient implementation of a concurrent coupling method called the Multiresolution Molecular Mechanics (MMM) for serial, parallel, and adaptive analysis. First, we present the features of the software implemented along with the associated technologies. The scalability of the software implementation is demonstrated, and the competing effects of multiscale modeling and parallelization are discussed. Then, the algorithms contributing to the efficiency of the software are presented. These include algorithms for eliminating latent ghost atoms from calculations and measurement-based dynamic balancing of parallel workload. The efficiency improvements made by these algorithms are demonstrated by benchmark tests. The efficiency of the software is found to be on par with LAMMPS, a state-of-the-art Molecular Dynamics (MD) simulation code, when performing full atomistic simulations. Speed-up of the MMM method is shown to be directly proportional to the reduction of the number of the atoms visited in force computation. Finally, an adaptive MMM analysis on a nanoindentation problem, containing over a million atoms, is performed, yielding an improvement of 6.3–8.5 times in efficiency, over the full atomistic MD method. For the first time, the efficiency of a concurrent atomistic/continuum coupling method is comprehensively investigated and demonstrated.

Multi-scale simulation method for electroosmotic flows

Electroosmotic transport in micro-and nano- channels has important applications in biological and engineering systems but is difficult to model because nanoscale structure near surfaces impacts flow throughout the channel. We develop an efficient multi-scale simulation method that treats near-wall and bulk subdomains with different physical descriptions and couples them through a finite overlap region. Molecular dynamics is used in the near-wall subdomain where the ion density is inconsistent with continuum models and the discrete structure of solvent molecules is important. In the bulk region the solvent is treated as a continuum fluid described by the incompressible Navier-Stokes equations with thermal fluctuations. A discrete description of ions is retained because of the low density of ions and the long range of electrostatic interactions. A stochastic Euler-Lagrangian method is used to simulate the dynamics of these ions in the implicit continuum solvent. The overlap region allows free exchange of solvent and ions between the two subdomains. The hybrid approach is validated against full molecular dynamics simulations for different geometries and types of flows.

Double-layer capacitance for a charged surface

Supercapacitors are a key technology for the energy storage requirements of future energy systems. A primary problem of supercapacitors is their limited energy density, but new electrode materials and electrode designs might help to overcome this limitation. Numerical modelling can be a valuable tool in this challenge, although realistic ab initio calculations are usually very cumbersome. In this work, we show that electric double-layer capacitors can be modelled to good accuracy by a coarse-grained sampling of the electrolyte’s configuration space rather than using full molecular dynamics simulations. This saves considerable computation time, and it allows for processing more materials and more complicated systems with modest computational effort.

The charge imbalance in ultracold plasmas

Ultracold plasmas are regarded as quasineutral but not strictly neutral. The results of charge imbalance in the expansion of ultracold plasmas are reported. The calculations are performed by a full molecular-dynamics simulation. The details of the electron velocity distributions are calculated without the assumption of electron global thermal equilibrium and Boltzmann distribution. Spontaneous evolutions of the charge imbalance from the initial states with perfect neutrality are given in the simulations. The expansion of outer plasma slows down with the charge imbalance. The influences of plasma size and parameters on the charge imbalance are discussed. The radial profiles of electron temperature are given for the first time, and the self-similar expansion can still occur even if there is no global thermal equilibrium. The electron disorder induced heating is also found in the simulation.

Programmed shape-dependence of shape memory effect of oriented polystyrene: A molecular dynamics study

Oriented polystyrene (PS) has attracted attention due to its capability of sequential self-folding behaviors by infrared (IR) light heating. It has been seen that temporal changes of the shape and properties of PS are affected by its pre-defined molecular structure. In this study, full atomistic molecular dynamics (MD) simulations are carried out to study the effect of initially applied strain on the thermoelastic properties and shape recovery behaviors of the oriented PS. The shape memory creation procedure (SMCP) is described by long-time simulation and initial strains between 15% and 100% are applied by in-plane tensile loadings. As the extent of pre-stretching increases, the anisotropy of elastic modulus and linear coefficient of thermal expansion (CTE) increase primarily due to the molecular alignment. The shape fixity ratio increases by up to 24% and the recovery ratio decreases by up to 32% by increasing the initial strain. In particular, the shape recovery ratio is mainly affected by the orientational order parameter of the oriented PS. The rate of the recoveries of the thermomechanical properties and shape reduce for a more pre-stretched PS. The retardation of conformational transformation comes from a reduction in the sizes of free volume elements. The results demonstrate a microstructure-property relationship which is important in designing the self-folding behaviors of oriented PS.

A Correlation between the Activity of Candida antarctica Lipase B and Differences in Binding Free Energies of Organic Solvent and Substrate

The ability of enzymes to operate in organic solvent is now widely accepted and is the basis for extensive research in enzymology. The challenge is to select the solvent media that allows the modulation of enzyme activity. For a rational selection of a solvent, it is necessary to understand the effect of organic solvent molecules on enzyme structure and the enzymatic reaction on a molecular level. To gain such insight, we combined experimental kinetics studies with full atomic molecular dynamics simulations and found a correlation between the activity of Candida antarctica lipase B (CALB) [for the esterification reaction between butyric acid and ethanol at a fixed water activity] and the binding of the solvent/substrate molecules in the active site region of CALB. We have investigated the influence of four organic solvents—hexane (HEX), methyl tertiary butyl ether (MTBE), acetonitrile (ACN), and tertiary butanol (TBU)—on the catalytic activity of CALB for the esterification reaction. The solvents have bee...

Full molecular dynamics simulations of liquid water and carbon tetrachloride for two-dimensional Raman spectroscopy in the frequency domain

Frequency-domain two-dimensional (2D) Raman signals, which are equivalent to coherent two-dimensional Raman scattering (COTRAS) signals, for liquid water and carbon tetrachloride were calculated using an equilibrium–nonequilibrium hybrid molecular dynamics (MD) simulation algorithm. An appropriate representation of the 2D Raman spectrum obtained from MD simulations provides an easy-to-understand depiction of structural and dynamical properties. We elucidate mechanisms governing the 2D signal profiles involving anharmonic mode–mode coupling and the nonlinearities of the polarizability for the intermolecular and intramolecular vibrational modes. The predicted signal profiles and intensities can be utilized to analyze recently developed single-beam 2D spectra, whose signals are generated from a coherently controlled pulse, allowing the single-beam measurement to be carried out more efficiently. Moreover, the MD simulation results allow us to visualize the molecular structure and dynamics by comparing the accurately calculated spectrum with experimental result.