The subfolder "Tutorial/topology" also contains other topologies used in publication. For this tutorial, we use 1600 beads of graphite, 50 molecules of AM25, and 300 molecules of solvent PHEO. The first four lines describe where parameters of force-field can be found (in subdirectory "Tutorial/FF"), then there is with a title of simulation, and then, after which there are types and numbers of molecules of each type used in the simulation. The topology file consist of references to parameters of force-fields and number of molecules in the system. Make an empty directory in which you will test the simulation protocol: For purposes of this tutorial this will be our working directory:
It expands to a directory or folder called Tutorial.
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As a solvent, we use phenyloctane, which in its coarse-grained representation consist of 5 beads (three SC4 beads in a ring and two C1 beads in a tail)ĭownload the zip file, and unzip it. For more information, look into publication. We will study here self-assembly of a linear functionalized alkane, AM25, which consist of 6 beads (two P1 polar and four C1 apolar beads, respectively, arranged as C1-P1-C1-C1-P1-C1), which can represent N,N′-decanomethylenebispentamide (C4H9-CO-NH-(CH2)10-NH-CO-C4H9). In this tutorial, we will perform a simple simulation of self-assembly (that is adsorption and rearrangement) on a graphite surface from a random configuration of adsorbent in a solvent. You can find tutorials on these topics at and. It is helpful to have a basic understanding of the gromacs molecular dynamics package and the Martini force-field. This tutorial assumes a basic knowledge of the Linux operating system and some experience with gromacs. it contains a method to construct a regularly packed surface consisting of a number of layers of beads: this method can be used to construct any such surface or crystal regardless of the nature of the beads or application it contains specific information to set up the self-assembly simulations of long-chain functionalized molecules on graphite All files for this tutorial can be found in this zip file. The tutorial is prepared for GROMACS 2016 versions and may need (small) changes in other versions. Such simulations can be done on a personal computer within 2h. For learning purposes, we will limit ourselves to a tiny graphite flake with a small number of adsorbent molecules. The Martini force-field was originally developed for lipids and then extended to many other systems including self-assembly on a graphite flake.
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This tutorial guides you on how to perform self-assembly simulations on a graphite flake using a special version of the coarse-grained force-field MARTINI, similar to work done in publication. Self-assembly of functionalized alkanes on a graphite surface Last Updated: Thursday, 21 November 2019 15:04
In this study, VMD and AGMD process have shown the potential to treat copper-containing solution.Physisorption on particle-based surfaces Details Meanwhile, AGMD was superior for energy saving compared with VMD. The maximum permeate flux and the minimum specific thermal energy consumption of VMD was 21.82 kg/m 2-h and 674.5 kWh/m 3 respectively. Moreover, the membrane module with high packing density performed better in utilizing lower thermal energy. It was found that enhancing membrane length would increase thermal consumption and pressure drop simultaneously. A relatively stable VMD performance with high rejection rate was achieved due to the chemical stability and the sponge-like structure of membrane. The impacts of various operating parameters and module parameters on VMD performance were studied in terms of permeate flux, rejection rate, total water production, specific thermal (electric) energy consumption, pressure drop and thermal efficiency. This study investigated the performance of VMD and AGMD system for separating water from copper-containing solution.
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