Probing the self-ionization of liquid water with ab initio deep potential molecular dynamics.
Marcos F Calegari AndradeRoberto CarAnnabella SelloniPublished in: Proceedings of the National Academy of Sciences of the United States of America (2023)
The chemical equilibrium between self-ionized and molecular water dictates the acid-base chemistry in aqueous solutions, yet understanding the microscopic mechanisms of water self-ionization remains experimentally and computationally challenging. Herein, Density Functional Theory (DFT)-based deep neural network (DNN) potentials are combined with enhanced sampling techniques and a global acid-base collective variable to perform extensive atomistic simulations of water self-ionization for model systems of increasing size. The explicit inclusion of long-range electrostatic interactions in the DNN potential is found to be crucial to accurately reproduce the DFT free energy profile of solvated water ion pairs in small (64 and 128 H 2 O) cells. The reversible work to separate the hydroxide and hydronium to a distance [Formula: see text] is found to converge for simulation cells containing more than 500 H 2 O, and a distance of [Formula: see text] 8 Å is the threshold beyond which the work to further separate the two ions becomes approximately zero. The slow convergence of the potential of mean force with system size is related to a restructuring of water and an increase of the local order around the water ions. Calculation of the dissociation equilibrium constant illustrates the key role of long-range electrostatics and entropic effects in the water autoionization process.
Keyphrases
- molecular dynamics
- density functional theory
- induced apoptosis
- molecular dynamics simulations
- neural network
- single molecule
- oxidative stress
- mass spectrometry
- smoking cessation
- human health
- gold nanoparticles
- signaling pathway
- climate change
- high resolution
- endoplasmic reticulum stress
- gas chromatography
- water soluble
- human milk
- tandem mass spectrometry
- liquid chromatography
- oxide nanoparticles