<i>Ab initio</i> molecular dynamics calculations of ion hydration free energies

Leung, Kevin; Rempe, Susan; Lilienfeld, O. Anatole von

doi:10.1063/1.3137054

Cited by 122 publications

(164 citation statements)

References 97 publications

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“…7 With DFT methods, we have so far unambiguously calculated q . 1 2 Even better agreement is obtained when comparing neutral ion pairs where ambiguities in cancel. To reiterate, no parameters in our model are adjusted to achieve a fit to experiment.…”

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confidence: 76%

“…To evaluate the quality of these predictions, we made a proper apples-to-apples comparison to tabulated data from experimental work. 2,3 The comment by Chen and Chen 4 reflects confusion about our choice of observable used to achieve a consistent comparison of predicted 1 and tabulated 2,3 ⌬G hyd , perhaps incorrectly implies that we adjusted free parameters to achieve a fit to experimental data, and overstates the utility of the Born hydration formula for ion hydration. Some of their apparent disagreement with our work appears more philosophical than technical in nature, but we welcome the opportunity to clarify our results in light of recent developments in this field.…”

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confidence: 99%

“…In our recent work, 1 we applied ab initio molecular dynamics ͑AIMD͒ simulations based on density functional theory ͑DFT͒ to predict the hydration free energy ͑⌬G hyd ͒ of several simple ions for the first time. To evaluate the quality of these predictions, we made a proper apples-to-apples comparison to tabulated data from experimental work.…”

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confidence: 99%

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Response to “Comment on ‘Ab initio molecular dynamics calculation of ion hydration free energies’ [J. Chem. Phys. 133, 047103 (2010)]”

Rempe

Leung

2010

The Journal of Chemical Physics

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confidence: 76%

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confidence: 99%

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Response to “Comment on ‘Ab initio molecular dynamics calculation of ion hydration free energies’ [J. Chem. Phys. 133, 047103 (2010)]”

Rempe

Leung

2010

The Journal of Chemical Physics

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“…[42] Sulpizi and Sprik [43] rigorously explored the need for fractional nuclear charge calculations to predict pK a 's of various organic and inorganic acids and bases. In the case of free energy differences, fractional charges can also be avoided all together within a simple alternative and elegant interpolation scheme put forth by Alfè et al [44] : atomic forces are evaluated at both endpoints (k 2 0; 1), and k dependent molecular dynamics trajectories are generated for atoms being propagated according to a linear combination of these forces using instantaneous k values as weights.…”

Section: Free Energy Applicationsmentioning

confidence: 99%

First principles view on chemical compound space: Gaining rigorous atomistic control of molecular properties

Lilienfeld

2013

Int J of Quantum Chemistry

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A well‐defined notion of chemical compound space (CCS) is essential for gaining rigorous control of properties through variation of elemental composition and atomic configurations. Here, we give an introduction to an atomistic first principles perspective on CCS. First, CCS is discussed in terms of variational nuclear charges in the context of conceptual density functional and molecular grand‐canonical ensemble theory. Thereafter, we revisit the notion of compound pairs, related to each other via “alchemical” interpolations involving fractional nuclear charges in the electronic Hamiltonian. We address Taylor expansions in CCS, property nonlinearity, improved predictions using reference compound pairs, and the ounce‐of‐gold prize challenge to linearize CCS. Finally, we turn to machine learning of analytical structure property relationships in CCS. These relationships correspond to inferred, rather than derived through variational principle, solutions of the electronic Schrödinger equation. © 2013 Wiley Periodicals, Inc.

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“…Furthermore, in the absence of accurate interatomic potentials it would be straightforward to use AIMD within the presented scheme. Alchemical changes within AIMD can be performed in a manner analogous to that described here [32,33]. The corresponding anticipated increase in computational cost could be mitigated by reducing the necessary number of mole fractions or through coarser integration of Eq.…”

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confidence: 99%

Molten salt eutectics from atomistic simulations

2011

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Despite their importance for solar thermal power applications, phase-diagrams of molten salt mixture heat transfer fluids (HTFs) are not readily accessible from first principles. We present a molecular dynamics scheme general enough to identify eutectics of any HTF candidate mixture. The eutectic mixture and temperature are located using the liquid mixture free energy and the pure component solid-liquid free energy differences. The liquid mixture free energy is obtained using thermodynamic integration over particle identity transmutations sampled with molecular dynamics at a single temperature. According to Carnot's cycle, the maximum efficiency of solar thermal power facilities increases with the temperature difference between melting and thermal decomposition of employed heat transfer fluids (HTFs). Consequently, new formulations of low melting but temperature resistant molten salt mixtures are actively sought [1]. Competitive formulations currently include eutectics of alkali and alkali-metal earth nitrates and nitrite mixtures. Unfortunately, the dimensionality of the combinatorial multicomponent space of all possible cations and anions prohibits exhaustive scanning using computer simulation. Once an optimal HTF formulation is identified, however, its realization through simple mixing is readily accomplished in experiment. Identifying new HTFs therefore represents a rewarding challenge for atomistic first principles materials design efforts using theory and computation. Ab initio (AI) based design, through an efficient combination of first principles methods and optimization algorithms [2], has already been applied to inverting band structures [3], identifying stable alloys [4], designing heterogeneous catalysts [5,6], or discovering ternary metal oxides for batteries [7]. Identity transformations, also called "alchemical" transmutations [8], have been successfully applied to compute compositions in the earth's core [9], phase stability in solid solutions [10], and a wide variety of biochemical applications [11], among others.The Gibbs criteria for phase equilibrium dictates that temperature, pressure, and chemical potential of individual components must be equal in coexisting phases. Therefore, knowledge not only of average liquid configurations but also of the solid mixture's structure is essential. For phase transitions of mixtures, the problem is hence strongly linked to the challenge of predicting molecular crystals from first principles [12], which has been addressed for co-crystals only recently [7,13] in mapping out entire phase diagrams. For the identification of HTF mixtures with minimal melting points, however, it is sufficient to simply focus on eutectics, rather than having to screen the entire solid-liquid phase diagram. Here, we present a first principles approach for directly estimating eutectic compositions and temperatures for any number of components, relying on a combination of only a couple of molecular dynamics (MD) calculations per mole fraction at a single temperature and knowledge ab...

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Ab initio molecular dynamics calculations of ion hydration free energies

Cited by 122 publications

References 97 publications

Response to “Comment on ‘Ab initio molecular dynamics calculation of ion hydration free energies’ [J. Chem. Phys. 133, 047103 (2010)]”

Response to “Comment on ‘Ab initio molecular dynamics calculation of ion hydration free energies’ [J. Chem. Phys. 133, 047103 (2010)]”

First principles view on chemical compound space: Gaining rigorous atomistic control of molecular properties

Molten salt eutectics from atomistic simulations

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