Controllers for imposing continuum-to-molecular boundary conditions in arbitrary fluid flow geometries

Matthew K. Borg; Graham B. Macpherson; Jason M. Reese

doi:10.1080/08927021003752812

Controllers for imposing continuum-to-molecular boundary conditions in arbitrary fluid flow geometries

Matthew K. Borg^*, Graham B. Macpherson, Jason M. Reese

^*Corresponding author for this work

School of Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

We present a new parallelised controller for steering an arbitrary geometric region of a molecular dynamics (MD) simulation towards a desired thermodynamic and hydrodynamic state. We show that the controllers may be applied anywhere in the domain to set accurately an initial MD state, or solely at boundary regions to prescribe non-periodic boundary conditions (PBCs) in MD simulations. The mean molecular structure and velocity autocorrelation function remain unchanged (when sampled a few molecular diameters away from the constrained region) when compared with those distributions measured using PBCs. To demonstrate the capability of our new controllers, we apply them as non-PBCs in parallel to a complex MD mixing nano-channel and in a hybrid MD continuum simulation with a complex coupling region. The controller methodology is easily extendable to polyatomic MD fluids.

Original language	English
Pages (from-to)	745-757
Number of pages	13
Journal	Molecular simulation
Volume	36
Issue number	10
DOIs	https://doi.org/10.1080/08927021003752812
Publication status	Published - 2010

Keywords / Materials (for Non-textual outputs)

molecular dynamics
hybrid molecular continuum simulations
boundary conditions
nanofluidics
thermodynamic state
controllers
dynamics
particles
numerical methods
parallel computation

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BorgEtAlMolSim2010Accepted author manuscript, 4.27 MB

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title = "Controllers for imposing continuum-to-molecular boundary conditions in arbitrary fluid flow geometries",

abstract = "We present a new parallelised controller for steering an arbitrary geometric region of a molecular dynamics (MD) simulation towards a desired thermodynamic and hydrodynamic state. We show that the controllers may be applied anywhere in the domain to set accurately an initial MD state, or solely at boundary regions to prescribe non-periodic boundary conditions (PBCs) in MD simulations. The mean molecular structure and velocity autocorrelation function remain unchanged (when sampled a few molecular diameters away from the constrained region) when compared with those distributions measured using PBCs. To demonstrate the capability of our new controllers, we apply them as non-PBCs in parallel to a complex MD mixing nano-channel and in a hybrid MD continuum simulation with a complex coupling region. The controller methodology is easily extendable to polyatomic MD fluids.",

keywords = "molecular dynamics, hybrid molecular continuum simulations, boundary conditions, nanofluidics, thermodynamic state, controllers, dynamics, particles, numerical methods, parallel computation",

author = "Borg, {Matthew K.} and Macpherson, {Graham B.} and Reese, {Jason M.}",

year = "2010",

doi = "10.1080/08927021003752812",

language = "English",

volume = "36",

pages = "745--757",

journal = "Molecular simulation",

issn = "0892-7022",

publisher = "Taylor & Francis",

number = "10",

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TY - JOUR

T1 - Controllers for imposing continuum-to-molecular boundary conditions in arbitrary fluid flow geometries

AU - Borg, Matthew K.

AU - Macpherson, Graham B.

AU - Reese, Jason M.

PY - 2010

Y1 - 2010

N2 - We present a new parallelised controller for steering an arbitrary geometric region of a molecular dynamics (MD) simulation towards a desired thermodynamic and hydrodynamic state. We show that the controllers may be applied anywhere in the domain to set accurately an initial MD state, or solely at boundary regions to prescribe non-periodic boundary conditions (PBCs) in MD simulations. The mean molecular structure and velocity autocorrelation function remain unchanged (when sampled a few molecular diameters away from the constrained region) when compared with those distributions measured using PBCs. To demonstrate the capability of our new controllers, we apply them as non-PBCs in parallel to a complex MD mixing nano-channel and in a hybrid MD continuum simulation with a complex coupling region. The controller methodology is easily extendable to polyatomic MD fluids.

AB - We present a new parallelised controller for steering an arbitrary geometric region of a molecular dynamics (MD) simulation towards a desired thermodynamic and hydrodynamic state. We show that the controllers may be applied anywhere in the domain to set accurately an initial MD state, or solely at boundary regions to prescribe non-periodic boundary conditions (PBCs) in MD simulations. The mean molecular structure and velocity autocorrelation function remain unchanged (when sampled a few molecular diameters away from the constrained region) when compared with those distributions measured using PBCs. To demonstrate the capability of our new controllers, we apply them as non-PBCs in parallel to a complex MD mixing nano-channel and in a hybrid MD continuum simulation with a complex coupling region. The controller methodology is easily extendable to polyatomic MD fluids.

KW - molecular dynamics

KW - hybrid molecular continuum simulations

KW - boundary conditions

KW - nanofluidics

KW - thermodynamic state

KW - controllers

KW - dynamics

KW - particles

KW - numerical methods

KW - parallel computation

U2 - 10.1080/08927021003752812

DO - 10.1080/08927021003752812

M3 - Article

SN - 0892-7022

VL - 36

SP - 745

EP - 757

JO - Molecular simulation

JF - Molecular simulation

IS - 10

ER -

Controllers for imposing continuum-to-molecular boundary conditions in arbitrary fluid flow geometries

Abstract

Keywords / Materials (for Non-textual outputs)

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