Your search keyword '"Bui, Anna T."' showing total 16 results

1. Learning classical density functionals for ionic fluids

Author

Bui, Anna T. and Cox, Stephen J.

Subjects

Condensed Matter - Statistical Mechanics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Soft Condensed Matter, Physics - Chemical Physics, Physics - Computational Physics

Abstract

Accurate and efficient theoretical techniques for describing ionic fluids are highly desirable for many applications across the physical, biological and materials sciences. With a rigorous statistical mechanical foundation, classical density functional theory (cDFT) is an appealing approach, but the competition between strong Coulombic interactions and steric repulsion limits the accuracy of current approximate functionals. Here, we extend a recently presented machine learning (ML) approach [Samm\"uller et al., Proc. Natl. Acad. Sci. USA, 120, e2312484120 (2023)] designed for systems with short-ranged interactions to ionic fluids. By adopting ideas from local molecular field theory, the framework we present amounts to using neural networks to learn the local relationship between the one-body direct correlation functions and inhomogeneous density profiles for a "mimic'' short-ranged system, with effects of long-ranged interactions accounted for in a mean-field, yet well-controlled, manner. By comparing to results from molecular simulations, we show that our approach accurately describes the structure and thermodynamics of the prototypical model for electrolyte solutions and ionic liquids: the restricted primitive model. The framework we present acts as an important step toward extending ML approaches for cDFT to systems with accurate interatomic potentials., Comment: Main: 7 pages, 3 figures. SI: 16 pages, 8 figures

Published

2024

2. Flow is slow at the nanoscale: Revisiting the Green-Kubo relation for friction

Author

Bui, Anna T. and Cox, Stephen J.

Subjects

Condensed Matter - Statistical Mechanics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Soft Condensed Matter, Physics - Chemical Physics

Abstract

A central aim of statistical mechanics is to establish connections between a system's microscopic fluctuations and its macroscopic response to a perturbation. For non-equilibrium transport properties, this amounts to establishing Green-Kubo (GK) relationships. In hydrodynamics, relating such GK expressions for liquid-solid friction to macroscopic slip boundary conditions has remained a long-standing problem due to two challenges: (i) The GK running integral of the force autocorrelation function decays to zero rather than reaching a well-defined plateau value; and (ii) debates persist on whether such a transport coefficient measures an intrinsic interfacial friction or an effective friction in the system. Inspired by ideas from the coarse-graining community, we derive a GK relation for liquid-solid friction where the force autocorrelation is sampled with a constraint of momentum conservation in the liquid. Our expression does not suffer from the "plateau problem" and unambiguously measures an effective friction coefficient, in an analogous manner to Stokes' law. We further establish a link between the derived friction coefficient and the hydrodynamic slip length, enabling a straightforward assessment of continuum hydrodynamics across length scales. We find that continuum hydrodynamics describes the simulation results quantitatively for confinement length all the way down to 1 nm. Our results also make clear that water flow under nano-confinement is orders of magnitude slower compared to the macroscopic case. Our approach amounts to a straightforward modification to the present standard method of quantifying interfacial friction from molecular simulations, making possible a sensible comparison between surfaces of vastly different slippage., Comment: Main: 11 pages, 3 figures. SI: 26 pages, 11 figures

Published

2024

3. A classical density functional theory for solvation across length scales

Author

Bui, Anna T. and Cox, Stephen J.

Subjects

Condensed Matter - Statistical Mechanics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Soft Condensed Matter, Physics - Chemical Physics

Abstract

A central aim of multiscale modeling is to use results from the Schr\"odinger Equation to predict phenomenology on length scales that far exceed those of typical molecular correlations. In this work, we present a new approach rooted in classical density functional theory (cDFT) that allows us to accurately describe the solvation of apolar solutes across length scales. Our approach builds on the Lum-Chandler-Weeks (LCW) theory of hydrophobicity [K. Lum et al., J. Phys. Chem. B 103, 4570 (1999)] by constructing a free energy functional that uses a slowly-varying component of the density field as a reference. From a practical viewpoint, the theory we present is numerically simpler and generalizes to solutes with soft-core repulsion more easily than LCW theory. Furthermore, by assessing the local compressibility and its critical scaling behavior, we demonstrate that our LCW-style cDFT approach contains the physics of critical drying, which has been emphasized as an essential aspect of hydrophobicity by recent theories. As our approach is parameterized on the two-body direct correlation function of the uniform fluid and the liquid-vapor surface tension, it straightforwardly captures the temperature dependence of solvation. Moreover, we use our theory to describe solvation at a first-principles level, on length scales that vastly exceed what is accessible to molecular simulations., Comment: Main: 11 pages, 4 figures. SI: 27 pages, 13 figures

Published

2024

4. Classical quantum friction at water-carbon interfaces

Author

Bui, Anna T., Thiemann, Fabian L., Michaelides, Angelos, and Cox, Stephen J.

Subjects

Condensed Matter - Soft Condensed Matter

Abstract

Friction at water-carbon interfaces remains a major puzzle with theories and simulations unable to explain experimental trends in nanoscale waterflow. A recent theoretical framework -- quantum friction (QF)-- proposes to resolve these experimental observations by considering nonadiabatic coupling between dielectric fluctuations in water and graphitic surfaces. Here, using a classical model that enables fine-tuning of the solid's dielectric spectrum, we provide evidence from simulations in general support of QF. In particular, as features in the solid's dielectric spectrum begin to overlap with water's librational and Debye modes, we find an increase in friction in line with that proposed by QF. At the microscopic level, we find that this contribution to friction manifests more distinctly in the dynamics of the solid's charge density than that of water. Our findings suggest that experimental signatures of QF may be more pronounced in the solid's response rather than liquid water's.

Published

2022

5. Ice interfaces: general discussion

Author

Advincula, Xavier R., primary, Backus, Ellen H. G., additional, Bartels-Rausch, Thorsten, additional, Benaglia, Simone, additional, Ben Ari, Gil, additional, Blow, Katarina E., additional, Bonn, Mischa, additional, Bui, Anna T., additional, Cox, Stephen J., additional, Della Pia, Flaviano, additional, Diebold, Ulrike, additional, Finney, Aaron R., additional, Franceschi, Giada, additional, Fumagalli, Laura, additional, Goel, Gaurav, additional, Hayton, John A., additional, Holdship, Charlie, additional, Jiang, Ying, additional, Jin, Di, additional, Kapil, Venkat, additional, Kavokine, Nikita, additional, Koga, Kenichiro, additional, Laage, Damien, additional, Lahav, Meir, additional, Miao, Shurui, additional, Michaelides, Angelos, additional, Mohandas, Nandita, additional, Morgenstern, Karina, additional, Mukherjee, Taritra, additional, Nagata, Yuki, additional, Olvera de la Cruz, Monica, additional, Pan, Ding, additional, Piaggi, Pablo M., additional, Rempe, Susan L. B., additional, Ryan, Paul, additional, Salzmann, Christoph G., additional, Sayer, Thomas, additional, Saykally, Richard J., additional, Shepelenko, Margarita, additional, Sosso, Gabriele C., additional, Whale, Thomas F., additional, White, Jessica Jein, additional, Willard, Adam P., additional, and Zhang, Peng, additional

Published

2024

6. Dynamics and nano-rheology of interfacial water: general discussion

Author

Advincula, Xavier R., primary, Blow, Katarina E., additional, Bonn, Mischa, additional, Bui, Anna T., additional, Cheng, Yafang, additional, Cox, Stephen J., additional, Della Pia, Flaviano, additional, Diebold, Ulrike, additional, Fumagalli, Laura, additional, Goel, Gaurav, additional, Hayton, John A., additional, Jiang, Ying, additional, Kapil, Venkat, additional, Kavokine, Nikita, additional, Koga, Kenichiro, additional, Laage, Damien, additional, Lahav, Meir, additional, Miao, Shurui, additional, Michaelides, Angelos, additional, Montero de Hijes, Pablo, additional, Morgenstern, Karina, additional, Mukherjee, Taritra, additional, O'Neill, Niamh, additional, Pan, Ding, additional, Piaggi, Pablo M., additional, Rempe, Susan L. B., additional, Salvalaglio, Matteo, additional, Salzmann, Christoph G., additional, Sayer, Thomas, additional, Shepelenko, Margarita, additional, Sosso, Gabriele C., additional, Wang, Shaoheng, additional, Webber, Beau, additional, Willard, Adam P., additional, and Yao, Yang, additional

Published

2024

7. Soft matter–water interface: general discussion

Author

Backus, Ellen H. G., primary, Ben Ari, Gil, additional, Benaglia, Simone, additional, Bonn, Mischa, additional, Bui, Anna T., additional, Cox, Stephen J., additional, Della Pia, Flaviano, additional, Fraxedas, Jordi, additional, Goel, Gaurav, additional, Jiang, Ying, additional, Jin, Di, additional, Koga, Kenichiro, additional, Laage, Damien, additional, Miao, Shurui, additional, Michaelides, Angelos, additional, Morgenstern, Karina, additional, Mukherjee, Taritra, additional, Nagata, Yuki, additional, Naito, Hidefumi, additional, Nir, Oded, additional, Olvera de la Cruz, Monica, additional, Orlikowska-Rzeznik, Hanna, additional, Pan, Ding, additional, Rempe, Susan L. B., additional, Salzmann, Christoph G., additional, Taira, Aoi, additional, Vilangottunjalil, Aswathi, additional, Wang, Shaoheng, additional, Willard, Adam P., additional, Yao, Yang, additional, and Yu, Junting, additional

Published

2024

8. Classical Quantum Friction at Water-Carbon Interfaces

Author

Bui, Anna T, Thiemann, Fabian L, Michaelides, Angelos, Cox, Stephen J, Bui, Anna T [0000-0003-0981-4329], Thiemann, Fabian L [0000-0003-2951-6740], Michaelides, Angelos [0000-0002-9169-169X], Cox, Stephen J [0000-0003-2708-8711], and Apollo - University of Cambridge Repository

Subjects

liquid−solid interfaces, nanoscale water, Mechanical Engineering, graphene, Soft Condensed Matter (cond-mat.soft), FOS: Physical sciences, General Materials Science, Bioengineering, General Chemistry, Condensed Matter - Soft Condensed Matter, Condensed Matter Physics, molecular dynamics, liquid−solid friction

Abstract

Friction at water-carbon interfaces remains a major puzzle with theories and simulations unable to explain experimental trends in nanoscale waterflow. A recent theoretical framework -- quantum friction (QF)-- proposes to resolve these experimental observations by considering nonadiabatic coupling between dielectric fluctuations in water and graphitic surfaces. Here, using a classical model that enables fine-tuning of the solid's dielectric spectrum, we provide evidence from simulations in general support of QF. In particular, as features in the solid's dielectric spectrum begin to overlap with water's librational and Debye modes, we find an increase in friction in line with that proposed by QF. At the microscopic level, we find that this contribution to friction manifests more distinctly in the dynamics of the solid's charge density than that of water. Our findings suggest that experimental signatures of QF may be more pronounced in the solid's response rather than liquid water's.

Published

2023

9. Trade-Off between Redox Potential and the Strength of Electrochemical CO2 Capture in Quinones

Author

Bui, Anna T, Hartley, Niamh A, Thom, Alex JW, Forse, Alexander C, Bui, Anna T [0000-0003-0981-4329], Hartley, Niamh A [0000-0003-1381-9026], Thom, Alex JW [0000-0002-2417-7869], Forse, Alexander C [0000-0001-9592-9821], and Apollo - University of Cambridge Repository

Subjects

3407 Theoretical and Computational Chemistry, 13 Climate Action, 34 Chemical Sciences, 3406 Physical Chemistry

Abstract

Electrochemical carbon dioxide capture recently emerged as a promising alternative approach to conventional energy-intensive carbon-capture methods. A common electrochemical capture approach is to employ redox-active molecules such as quinones. Upon electrochemical reduction, quinones become activated for the capture of CO2 through a chemical reaction. A key disadvantage of this method is the possibility of side-reactions with oxygen, which is present in almost all gas mixtures of interest for carbon capture. This issue can potentially be mitigated by fine-tuning redox potentials through the introduction of electron-withdrawing groups on the quinone ring. In this article, we investigate the thermodynamics of the electron transfer and chemical steps of CO2 capture in different quinone derivatives with a range of substituents. By combining density functional theory calculations and cyclic voltammetry experiments, we support a previously described trade-off between the redox potential and the strength of CO2 capture. We show that redox potentials can readily be tuned to more positive values to impart stability to oxygen, but significant decreases in CO2 binding free energies are observed as a consequence. Our calculations support this effect for a large series of anthraquinones and benzoquinones. Different trade-off relationships were observed for the two classes of molecules. These trade-offs must be taken into consideration in the design of improved redox-active molecules for electrochemical CO2 capture.

Published

2022

10. Classical Quantum Friction at Water–Carbon Interfaces

Author

Bui, Anna T., primary, Thiemann, Fabian L., additional, Michaelides, Angelos, additional, and Cox, Stephen J., additional

Published

2023

11. Trade-Off between Redox Potential and the Strength of Electrochemical CO2 Capture in Quinones

Author

Bui, Anna T., primary, Hartley, Niamh A., additional, Thom, Alex J. W., additional, and Forse, Alexander C., additional

Published

2022

12. Trade-off between redox potential and strength of electrochemical CO2 capture in quinones

Author

Bui, Anna T., primary, Hartley, Niamh A., additional, Thom, Alex J. W., additional, and Forse, Alexander C., additional

Published

2022

13. Trade-off between redox potential and strength of electrochemical CO2 capture in quinones

Author

Bui, Anna T, primary, Hartley, Niamh A, additional, Thom, Alex J W, additional, and Forse, Alexander C, additional

Published

2022

14. Trade-Off between Redox Potential and the Strength of Electrochemical CO2 Capture in Quinones.

Author

Bui, Anna T., Hartley, Niamh A., Thom, Alex J. W., and Forse, Alexander C.

Published

2022

15. Trade-Off between Redox Potential and the Strength of Electrochemical CO2Capture in Quinones

Author

Bui, Anna T., Hartley, Niamh A., Thom, Alex J. W., and Forse, Alexander C.

Abstract

Electrochemical carbon dioxide capture recently emerged as a promising alternative approach to conventional energy-intensive carbon-capture methods. A common electrochemical capture approach is to employ redox-active molecules such as quinones. Upon electrochemical reduction, quinones become activated for the capture of CO2through a chemical reaction. A key disadvantage of this method is the possibility of side-reactions with oxygen, which is present in almost all gas mixtures of interest for carbon capture. This issue can potentially be mitigated by fine-tuning redox potentials through the introduction of electron-withdrawing groups on the quinone ring. In this article, we investigate the thermodynamics of the electron transfer and chemical steps of CO2capture in different quinone derivatives with a range of substituents. By combining density functional theory calculations and cyclic voltammetry experiments, we support a previously described trade-off between the redox potential and the strength of CO2capture. We show that redox potentials can readily be tuned to more positive values to impart stability to oxygen, but significant decreases in CO2binding free energies are observed as a consequence. Our calculations support this effect for a large series of anthraquinones and benzoquinones. Different trade-off relationships were observed for the two classes of molecules. These trade-offs must be taken into consideration in the design of improved redox-active molecules for electrochemical CO2capture.

Published

2022

16. Trade-Off between Redox Potential and the Strength of Electrochemical CO 2 Capture in Quinones.

Author

Bui AT, Hartley NA, Thom AJW, and Forse AC

Abstract

Electrochemical carbon dioxide capture recently emerged as a promising alternative approach to conventional energy-intensive carbon-capture methods. A common electrochemical capture approach is to employ redox-active molecules such as quinones. Upon electrochemical reduction, quinones become activated for the capture of CO 2 through a chemical reaction. A key disadvantage of this method is the possibility of side-reactions with oxygen, which is present in almost all gas mixtures of interest for carbon capture. This issue can potentially be mitigated by fine-tuning redox potentials through the introduction of electron-withdrawing groups on the quinone ring. In this article, we investigate the thermodynamics of the electron transfer and chemical steps of CO 2 capture in different quinone derivatives with a range of substituents. By combining density functional theory calculations and cyclic voltammetry experiments, we support a previously described trade-off between the redox potential and the strength of CO 2 capture. We show that redox potentials can readily be tuned to more positive values to impart stability to oxygen, but significant decreases in CO 2 binding free energies are observed as a consequence. Our calculations support this effect for a large series of anthraquinones and benzoquinones. Different trade-off relationships were observed for the two classes of molecules. These trade-offs must be taken into consideration in the design of improved redox-active molecules for electrochemical CO 2 capture., Competing Interests: The authors declare no competing financial interest., (© 2022 The Authors. Published by American Chemical Society.)

Published

2022