Schottky barrier photodetectors based on AlGaN

Here we present a program aimed at free-energy calculations in molecular systems. It consists of a series of routines that can be interfaced with the most popular classical molecular dynamics (MD) codes through a simple patching procedure. This leaves the possibility for the user to exploit many different MD engines depending on the system simulated and on the computational resources available. Free-energy calculations can be performed as a function of many collective variables, with a particular focus on biological problems, and using state-of-the-art methods such as metadynamics, umbrella sampling and Jarzynski-equation based steered MD. The present software, written in ANSI-C language, can be easily interfaced with both fortran and C/C++ codes.

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Stable prenucleation mineral clusters are liquid-like ionic polymers

Demichelis

et al. 2011

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Calcium carbonate is an abundant substance that can be created in several mineral forms by the reaction of dissolved carbon dioxide in water with calcium ions. Through biomineralization, organisms can harness and control this process to form various functional materials that can act as anything from shells through to lenses. The early stages of calcium carbonate formation have recently attracted attention as stable prenucleation clusters have been observed, contrary to classical models. Here we show, using computer simulations combined with the analysis of experimental data, that these mineral clusters are made of an ionic polymer, composed of alternating calcium and carbonate ions, with a dynamic topology consisting of chains, branches and rings. The existence of a disordered, flexible and strongly hydrated precursor provides a basis for explaining the formation of other liquid-like amorphous states of calcium carbonate, in addition to the non-classical behaviour during growth of amorphous calcium carbonate.

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Efficient Reconstruction of Complex Free Energy Landscapes by Multiple Walkers Metadynamics

et al. 2005

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Recently, we have introduced a new method, metadynamics, which is able to sample rarely occurring transitions and to reconstruct the free energy as a function of several variables with a controlled accuracy. This method has been successfully applied in many different fields, ranging from chemistry to biophysics and ligand docking and from material science to crystal structure prediction. We present an important development that speeds up metadynamics calculations by orders of magnitude and renders the algorithm much more robust. We use multiple interacting simulations, walkers, for exploring and reconstructing the same free energy surface. Each walker contributes to the history-dependent potential that, in metadynamics, is an estimate of the free energy. We show that the error on the reconstructed free energy does not depend on the number of walkers, leading to a fully linear scaling algorithm even on inexpensive loosely coupled clusters of PCs. In addition, we show that the accuracy and stability of the method are much improved by combining it with a weighted histogram analysis. We check the validity of our new method on a realistic application.

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Microscopic Evidence for Liquid-Liquid Separation in Supersaturated CaCO ₃ Solutions

Wallace

Hedges

Fernández-Martı́nez

et al. 2013

Science

474

491

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Recent experimental observations of the onset of calcium carbonate (CaCO3) mineralization suggest the emergence of a population of clusters that are stable rather than unstable as predicted by classical nucleation theory. This study uses molecular dynamics simulations to probe the structure, dynamics, and energetics of hydrated CaCO3 clusters and lattice gas simulations to explore the behavior of cluster populations before nucleation. Our results predict formation of a dense liquid phase through liquid-liquid separation within the concentration range in which clusters are observed. Coalescence and solidification of nanoscale droplets results in formation of a solid phase, the structure of which is consistent with amorphous CaCO3. The presence of a liquid-liquid binodal enables a diverse set of experimental observations to be reconciled within the context of established phase-separation mechanisms.

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Paolo Raiteri

PLUMED: A portable plugin for free-energy calculations with molecular dynamics

Stable prenucleation mineral clusters are liquid-like ionic polymers

Efficient Reconstruction of Complex Free Energy Landscapes by Multiple Walkers Metadynamics

Microscopic Evidence for Liquid-Liquid Separation in Supersaturated CaCO ₃ Solutions

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Product

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About

Paolo Raiteri

PLUMED: A portable plugin for free-energy calculations with molecular dynamics

Stable prenucleation mineral clusters are liquid-like ionic polymers

Efficient Reconstruction of Complex Free Energy Landscapes by Multiple Walkers Metadynamics

Microscopic Evidence for Liquid-Liquid Separation in Supersaturated CaCO 3 Solutions

Contact Info

Product

Resources

About

Microscopic Evidence for Liquid-Liquid Separation in Supersaturated CaCO ₃ Solutions