# Extended MARTINI Water Model for Heat Transfer Studies

**Authors:** Sumith Yesudasan

arXiv: 1906.11035 · 2019-11-28

## TL;DR

The paper introduces a reparametrized MARTINI water model, called MARTINI-E, optimized for high-temperature phase change simulations, outperforming existing models in reproducing key thermodynamic properties at 100°C.

## Contribution

A novel reparametrization of the MARTINI water model using advanced optimization techniques for accurate high-temperature phase change simulations.

## Key findings

- MARTINI-E accurately reproduces density, vaporization enthalpy, and surface tension at 100°C.
- Outperforms other coarse grain water models in high-temperature property predictions.
- Validated through energy conservation and latent heat measurements in lamellar systems.

## Abstract

The computationally efficient classical MARTINI model is extended to simulate heat transfer simulations of water. The current MARTINI model, variations of it and other coarse grain water models focus on reproducing the thermodynamic properties below room temperature, hence making them unsuitable for studying high temperature simulations especially evaporation at 100 {\deg}C. In this work, the MARTINI model is reparametrized using a combination of Genetic Algorithm, Artificial Neural Network and Nelder-Mead optimization technique to match the phase equilibrium properties of water. The reparametrized model (MARTINI-E) accurately reproduces density, enthalpy of vaporization and surface tension at 100{\deg}C and outperforms other leading coarse grain water models. The model is also validated using the energy conservation and enthalpy change due to latent heat in a lamellar system. This new water model can be used for simulating phase change phenomena, thin film evaporation and other energy transport mechanisms accurately.

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Source: https://tomesphere.com/paper/1906.11035