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1,139 results on '"Hermansson, Kersti"'

1. A foundation model for atomistic materials chemistry

Author

Batatia, Ilyes, Benner, Philipp, Chiang, Yuan, Elena, Alin M., Kovács, Dávid P., Riebesell, Janosh, Advincula, Xavier R., Asta, Mark, Avaylon, Matthew, Baldwin, William J., Berger, Fabian, Bernstein, Noam, Bhowmik, Arghya, Blau, Samuel M., Cărare, Vlad, Darby, James P., De, Sandip, Della Pia, Flaviano, Deringer, Volker L., Elijošius, Rokas, El-Machachi, Zakariya, Falcioni, Fabio, Fako, Edvin, Ferrari, Andrea C., Genreith-Schriever, Annalena, George, Janine, Goodall, Rhys E. A., Grey, Clare P., Grigorev, Petr, Han, Shuang, Handley, Will, Heenen, Hendrik H., Hermansson, Kersti, Holm, Christian, Jaafar, Jad, Hofmann, Stephan, Jakob, Konstantin S., Jung, Hyunwook, Kapil, Venkat, Kaplan, Aaron D., Karimitari, Nima, Kermode, James R., Kroupa, Namu, Kullgren, Jolla, Kuner, Matthew C., Kuryla, Domantas, Liepuoniute, Guoda, Margraf, Johannes T., Magdău, Ioan-Bogdan, Michaelides, Angelos, Moore, J. Harry, Naik, Aakash A., Niblett, Samuel P., Norwood, Sam Walton, O'Neill, Niamh, Ortner, Christoph, Persson, Kristin A., Reuter, Karsten, Rosen, Andrew S., Schaaf, Lars L., Schran, Christoph, Shi, Benjamin X., Sivonxay, Eric, Stenczel, Tamás K., Svahn, Viktor, Sutton, Christopher, Swinburne, Thomas D., Tilly, Jules, van der Oord, Cas, Varga-Umbrich, Eszter, Vegge, Tejs, Vondrák, Martin, Wang, Yangshuai, Witt, William C., Zills, Fabian, and Csányi, Gábor

Subjects
Physics - Chemical Physics, Condensed Matter - Materials Science
Abstract

Machine-learned force fields have transformed the atomistic modelling of materials by enabling simulations of ab initio quality on unprecedented time and length scales. However, they are currently limited by: (i) the significant computational and human effort that must go into development and validation of potentials for each particular system of interest; and (ii) a general lack of transferability from one chemical system to the next. Here, using the state-of-the-art MACE architecture we introduce a single general-purpose ML model, trained on a public database of 150k inorganic crystals, that is capable of running stable molecular dynamics on molecules and materials. We demonstrate the power of the MACE-MP-0 model - and its qualitative and at times quantitative accuracy - on a diverse set problems in the physical sciences, including the properties of solids, liquids, gases, chemical reactions, interfaces and even the dynamics of a small protein. The model can be applied out of the box and as a starting or "foundation model" for any atomistic system of interest and is thus a step towards democratising the revolution of ML force fields by lowering the barriers to entry., Comment: 119 pages, 63 figures, 37MB PDF

Published
2023

2. The entropic origin of the enhancement of liquid diffusion at the confining wall

Author

Agosta, Lorenzo, Dzugutov, Mikhail, Briels, Wim, and Hermansson, Kersti

Subjects
Condensed Matter - Materials Science, Physics - Chemical Physics, Physics - Computational Physics
Abstract

We report a molecular dynamics simulation investigating the dynamics of a simple liquid in the proximity to a non-interacting smooth confining wall. A strong enhancement of the liquid diffusion is observed within the layers adjacent to the wall. We present an analysis of these results in terms of the scaling law earlier reported by one of us that relates the liquid diffusion rate to the excess entropy. It is demonstrated that this scaling law can successfully account for the observed diffusion enhancement in the liquid near to the confining wall. We show that the proximity of a confining wall results in the decrease of (the absolute value of) the local excess entropy in the liquid layers closest to the wall which induces the observed diffusion enhancement in these layers. These results thereby show that the application scope of the scaling law which has so far only been used for the description of the bulk liquid diffusion can be extended to the diffusion in liquids under nano-scale confinement.

Published
2023

3. Reducing Training Data Needs with Minimal Multilevel Machine Learning (M3L)

Author

Heinen, Stefan, Khan, Danish, von Rudorff, Guido Falk, Karandashev, Konstantin, Arrieta, Daniel Jose Arismendi, Price, Alastair J. A., Nandi, Surajit, Bhowmik, Arghya, Hermansson, Kersti, and von Lilienfeld, O. Anatole

Subjects
Physics - Chemical Physics
Abstract

For many machine learning applications in science, data acquisition, not training, is the bottleneck even when avoiding experiments and relying on computation and simulation. Correspondingly, and in order to reduce cost and carbon footprint, training data efficiency is key. We introduce minimal multilevel machine learning (M3L) which optimizes training data set sizes using a loss function at multiple levels of reference data in order to minimize a combination of prediction error with overall training data acquisition costs (as measured by computational wall-times). Numerical evidence has been obtained for calculated atomization energies and electron affinities of thousands of organic molecules at various levels of theory including HF, MP2, DLPNO-CCSD(T), DFHFCABS, PNOMP2F12, and PNOCCSD(T)F12, and treating tens with basis sets TZ, cc-pVTZ, and AVTZ-F12. Our M3L benchmarks for reaching chemical accuracy in distinct chemical compound sub-spaces indicate substantial computational cost reductions by factors of $\sim$ 1.01, 1.1, 3.8, 13.8 and 25.8 when compared to heuristic sub-optimal multilevel machine learning (M2L) for the data sets QM7b, QM9$^\mathrm{LCCSD(T)}$, EGP, QM9$^\mathrm{CCSD(T)}_\mathrm{AE}$, and QM9$^\mathrm{CCSD(T)}_\mathrm{EA}$, respectively. Furthermore, we use M2L to investigate the performance for 76 density functionals when used within multilevel learning and building on the following levels drawn from the hierarchy of Jacobs Ladder:~LDA, GGA, mGGA, and hybrid functionals. Within M2L and the molecules considered, mGGAs do not provide any noticeable advantage over GGAs. Among the functionals considered and in combination with LDA, the three on average top performing GGA and Hybrid levels for atomization energies on QM9 using M3L correspond respectively to PW91, KT2, B97D, and $\tau$-HCTH, B3LYP$\ast$(VWN5), TPSSH.

Published
2023

4. Evolutionary Monte Carlo of QM properties in chemical space: Electrolyte design

Author

Karandashev, Konstantin, Weinreich, Jan, Heinen, Stefan, Arrieta, Daniel Jose Arismendi, von Rudorff, Guido Falk, Hermansson, Kersti, and von Lilienfeld, O. Anatole

Subjects
Physics - Chemical Physics
Abstract

Optimizing a target function over the space of organic molecules is an important problem appearing in many fields of applied science, but also a very difficult one due to the vast number of possible molecular systems. We propose an Evolutionary Monte Carlo algorithm for solving such problems which is capable of straightforwardly tuning both exploration and exploitation characteristics of an optimization procedure while retaining favourable properties of genetic algorithms. The method, dubbed MOSAiCS (Metropolis Optimization by Sampling Adaptively in Chemical Space), is tested on problems related to optimizing components of battery electrolytes, namely minimizing solvation energy in water or maximizing dipole moment while enforcing a lower bound on the HOMO-LUMO gap; optimization was done over sets of molecular graphs inspired by QM9 and Electrolyte Genome Project (EGP) datasets. MOSAiCS reliably generated molecular candidates with good target quantity values, which were in most cases better than the ones found in QM9 or EGP. While the optimization results presented in this work sometimes required up to $10^{6}$ QM calculations and were thus only feasible thanks to computationally efficient ab initio approximations of properties of interest, we discuss possible strategies for accelerating MOSAiCS using machine learning approaches.

Published
2023
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5. The entropic origin of the enhancement of liquid diffusion close to a neutral confining surface.

Author

Agosta, Lorenzo, Briels, Wim, Hermansson, Kersti, and Dzugutov, Mikhail

Subjects
KIRKENDALL effect, MOLECULAR dynamics, LIQUIDS, ENTROPY
Abstract

It is known that, in the proximity of a neutral wall, liquids experience diffusion enhancement relative to their bulk diffusion, but the origin of this phenomenon is still unknown. We report a molecular dynamics simulation investigating the dynamics of a simple liquid in the proximity to a non-interacting smooth confining wall, which exhibits a strong diffusion enhancement within the liquid layers adjacent to the wall. We present an analysis of these results, demonstrating that the observed diffusion enhancement can be accounted for, with numerical accuracy, using the universal scaling law that relates the liquid diffusion rate to the excess entropy. These results show that the scaling law, which has so far only been used for the description of the bulk liquid diffusion, can be successfully used to describe the diffusion in liquids under nano-scale confinement. [ABSTRACT FROM AUTHOR]

Published
2024
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6. A polarizable valence electron density based force field for high-energy interactions between atoms and molecules.

Author

Romero, José, Limão-Vieira, Paulo, Maihom, Thana, Hermansson, Kersti, and Probst, Michael

Subjects
CONDUCTION electrons, ELECTRON density, MOLECULAR force constants, FORCE density, MOLECULAR polarizability, PLASMA gases
Abstract

High-accuracy molecular force field models suited for hot gases and plasmas are not as abundant as those geared toward ambient pressure and temperature conditions. Here, we present an improved version of our previous electron-density based force field model that can now account for polarization effects by adjusting the atomic valence electron contributions to match ab initio calculated Mulliken partial charges. Using a slightly modified version of the Hohenberg–Kohn theorem, we also include an improved theoretical formulation of our model when applied to systems with degenerate ground states. We present two variants of our polarizable model, fitted from ab initio reference data calculated at CCSD(T)/cc-pVTZ and CCSD(T)/CEP-31G levels of theory, that both accurately model water dimer interaction energies. Further improvements include the additional interaction components with fictitious non-spherically symmetric, yet atom-centered, electron densities and fitting the exchange and correlation coefficients against analytical expressions. The latter removes all unphysical oscillations that are observed in the previous non-polarizable variant of our force field. [ABSTRACT FROM AUTHOR]

Published
2024
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8. Data Management Plans: the Importance of Data Management in the BIG-MAP Project

Author

Castelli, Ivano E., Arismendi-Arrieta, Daniel J., Bhowmik, Arghya, Cekic-Laskovic, Isidora, Clark, Simon, Dominko, Robert, Flores, Eibar, Flowers, Jackson, Frederiksen, Karina Ulvskov, Friis, Jesper, Grimaud, Alexis, Hansen, Karin Vels, Hardwick, Laurence J., Hermansson, Kersti, Königer, Lukas, Lauritzen, Hanne, Cras, Frédéric Le, Li, Hongjiao, Lyonnard, Sandrine, Lorrmann, Henning, Marzari, Nicola, Niedzicki, Leszek, Pizzi, Giovanni, Rahmanian, Fuzhan, Stein, Helge, Uhrin, Martin, Wenzel, Wolfgang, Winter, Martin, Wölke, Christian, and Vegge, Tejs

Subjects
Condensed Matter - Materials Science
Abstract

Open access to research data is increasingly important for accelerating research. Grant authorities therefore request detailed plans for how data is managed in the projects they finance. We have recently developed such a plan for the EU-H2020 BIG-MAP project - a cross-disciplinary project targeting disruptive battery-material discoveries. Essential for reaching the goal is extensive sharing of research data across scales, disciplines and stakeholders, not limited to BIG-MAP and the European BATTERY 2030+ initiative but within the entire battery community. The key challenges faced in developing the data management plan for such a large and complex project were to generate an overview of the enormous amount of data that will be produced, to build an understanding of the data flow within the project and to agree on a roadmap for making all data FAIR. This paper describes the process we followed and how we structured the plan., Comment: 12 pages, 4 figures; the full DMP is published as Supporting Information

Published
2021

9. Temperature effects on the ionic conductivity in concentrated alkaline electrolyte solutions

Author

Shao, Yunqi, Hellström, Matti, Yllö, Are, Mindemark, Jonas, Hermansson, Kersti, Behler, Jörg, and Zhang, Chao

Subjects
Physics - Chemical Physics, Condensed Matter - Soft Condensed Matter
Abstract

Alkaline electrolyte solutions are important components in rechargeable batteries and alkaline fuel cells. As the ionic conductivity is thought to be a limiting factor in the performance of these devices, which are often operated at elevated temperatures, its temperature dependence is of significant interest. Here we use NaOH as a prototypical example of alkaline electrolytes, and for this system we have carried out reactive molecular dynamics simulations with an experimentally verified high-dimensional neural network potential derived from density-functional theory calculations. It is found that in concentrated NaOH solutions elevated temperatures enhance both the contributions from proton transfer to the ionic conductivity and deviations from the Nernst-Einstein relation. These findings are expected to be of practical relevance for electrochemical devices based on alkaline electrolyte solutions.

Published
2019
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10. H2O2(s) and H2O2·2H2O(s) crystals compared with ices: DFT functional assessment and D3 analysis.

Author

Arismendi-Arrieta, Daniel J., Sen, Anik, Eriksson, Anders, Broqvist, Peter, Kullgren, Jolla, and Hermansson, Kersti

Subjects
DENSITY functionals, FUNCTIONAL assessment, DENSITY functional theory, ICE crystals, FUNCTIONALS, ICE, ENERGY consumption
Abstract

The H2O and H2O2 molecules resemble each other in a multitude of ways as has been noted in the literature. Here, we present density functional theory (DFT) calculations for the H2O2(s) and H2O2·2H2O(s) crystals and make selected comparisons with ice polymorphs. The performance of a number of dispersion-corrected density functionals—both self-consistent and a posteriori ones—are assessed, and we give special attention to the D3 correction and its effects. The D3 correction to the lattice energies is large: for H2O2(s) the D3 correction constitutes about 25% of the lattice energy using PBE, much more for RPBE, much less for SCAN, and it primarily arises from non-H-bonded interactions out to about 5 Å.The large D3 corrections to the lattice energies are likely a consequence of several effects: correction for missing dispersion interaction, the ability of D3 to capture and correct various other kinds of limitations built into the underlying DFT functionals, and finally some degree of cell-contraction-induced polarization enhancement. We find that the overall best-performing functionals of the twelve examined are optPBEvdW and RPBE-D3. Comparisons with DFT assessments for ices in the literature show that where the same methods have been used, the assessments largely agree. [ABSTRACT FROM AUTHOR]

Published
2023
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13. Water on ceria{111}: Comparison between 23 experimental vibrational studies in the literature and new modeling.

Author

Röckert, Andreas, Kullgren, Jolla, Sethio, Daniel, Agosta, Lorenzo, and Hermansson, Kersti

Subjects
DENSITY functional theory, ELECTRIC fields
Abstract

Theoretical and experimental vibrational signatures of H2O and OH (dissociated water) adsorbed on stoichiometric ceria{111} surfaces are compared. The experimental ones were collected from low-coverage experiments in the literature, and the theoretical anharmonic frequencies were generated using density functional theory calculations employing the optPBE-vdW functional for coverages from 0.5 to a few monolayers. It is found that (i) the experiments and our calculations overall agree well, lending credibility to both; (ii) the calculations manage to resolve the large class of H-bonded motifs into frequency classes that can guide experimental assignments; (iii) it is possible to find a geometrical H-bond definition that also captures the OH vibrational frequency downshifts well: R(H⋯O) ≤ 2.5 Å and the O–H⋯O angle θ ≥ 100°; and (iv) the frequency vs electric field relations for water and hydroxides (i.e., dissociated water) follow different and well-separated curves. [ABSTRACT FROM AUTHOR]

Published
2023
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17. A Simple Electron-Density Based Force Field Model for High-Energy Interactions between Atoms and Molecules

Author

Romero, José, Limão-Vieira, Paulo, Hermansson, Kersti, Probst, Michael, Romero, José, Limão-Vieira, Paulo, Hermansson, Kersti, and Probst, Michael

Abstract

In high-energy molecular dynamics or Monte Carlo simulations, standard force fields optimized for simulations at ambient temperatures are inadequate. This is largely because their repulsive parts have been regarded as not very significant, even well below zero interaction energies. It is, therefore, not obvious which force fields to resort to for simulating hot gases or plasmas. A force field model that uses the electronic densities of noninteracting atoms or molecules within the pair approximation is introduced. We start by deriving a naive model that neglects any exchange and correlation effects between the electronic clouds and then correct this model by adding a term calibrated from ab initio calculations using the CCSD(T)/cc-pVTZ level of theory. The resulting expression for this term can be regarded as a simple exchange-correlation function. We compare the results for the repulsive part of the potential energy hypersurfaces with the force fields commonly used on some dimers of small molecules.

Published
2024
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21. Toward an efficient f-in-core/f-in-valence switchable description for DFTB calculations of Ce 4f states in ceria.

Author

Kocmaruk, Bojana, Ammothum Kandy, Akshay Krishna, Hermansson, Kersti, Kullgren, Jolla, and Broqvist, Peter

Subjects
DENSITY functionals, ELECTRON configuration, OXIDATION states
Abstract

A computational protocol is developed for efficient studies of partially reduced redox-active oxides using the self-consistent charge density functional tight-binding method. The protocol is demonstrated for ceria, which is a prototypical reducible oxide material. The underlying idea is to achieve a consistent (and harmonized) set of Slater–Koster (SK) tables with connected repulsive potentials that enable switching on and off the in-valence description of the Ce 4f states without serious loss of accuracy in structure and energetics. The implicit treatment of the Ce 4f states, with the use of f-in-core SK-tables, is found to lead to a significant decrease in computational time. More importantly, it allows for explicit control of the oxidation states of individual Ce atoms. This makes it possible to "freeze" the electronic configuration, thereby allowing the exploration of the energetics for various meta-stable configurations. We anticipate that the outlined strategy can help to shed light on the interplay between the size, shape, and redox activity for nanoceria and other related materials. [ABSTRACT FROM AUTHOR]

Published
2023
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22. Comment on 'First-principles study of the influence of (110)-oriented strain on the ferroelectric properties of rutile TiO2' [arXiv:1106.2820]

Author

Refson, Keith, Montanari, Barbara, Mitev, Pavlin D., Hermansson, Kersti, and Harrison, Nicholas M.

Subjects
Condensed Matter - Materials Science, Physics - Computational Physics
Abstract

In a recent article, Gr\"{u}nebohm et al. [Phys. Rev. B 84 132105 (2011), arXiv:1106.2820] report that they fail to reproduce the A2u ferroelectric instability of TiO2 in the rutile structure calculated with density functional theory within the PBE-GGA approximation by Montanari et al. [Chem. Phys. Lett 364, 528 (2002)]. We demonstrate that this disagreement arises from an erroneous treatment of Ti 3s and 3p semi-core electrons as core in their calculations. Fortuitously the effect of the frozen semi-core pseudopotential cancels the phonon instability of the PBE exchange-correlation, and the combination yields phonon frequencies similar to the LDA harmonic values. Gr\"{u}nebohm et al. also attempted and failed to reproduce the soft acoustic phonon mode instability under (110) strain reported by Mitev et al. [Phys. Rev. B 81 134303 (2010)]. For this mode the combination of PBE-GGA and frozen semi-core yields a small imaginary frequency of 9.8i. The failure of Gr\"{u}nebohm et al. to find this mode probably arose from numerical limitations of the geometry optimization approach in the presence of a shallow double well potential; the optimization method is not suitable for locating such instabilities., Comment: 5 pages

Published
2013
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24. Adsorption of Glycine on TiO2in Water from On-the-fly Free-Energy Calculations and In Situ Electrochemical Impedance Spectroscopy

Author

Agosta, Lorenzo, Fiore, Luca, Colozza, Noemi, Pérez-Ropero, Guillermo, Lyubartsev, Alexander, Arduini, Fabiana, and Hermansson, Kersti

Abstract

We report here an experimental-computational study of hydrated TiO2anatase nanoparticles interacting with glycine, where we obtain quantitative agreement of the measured adsorption free energies. Ab initio simulations are performed within the tight binding and density functional theory in combination with enhanced free-energy sampling techniques, which exploit the thermodynamic integration of the unbiased mean forces collected on-the-fly along the molecular dynamics trajectories. The experiments adopt a new and efficient setup for electrochemical impedance spectroscopy measurements based on portable screen-printed gold electrodes, which allows fast and in situ signal assessment. The measured adsorption free energy is −30 kJ/mol (both from experiment and calculation), with preferential interaction of the charged NH3+group which strongly adsorbs on the TiO2bridging oxygens. This highlights the importance of the terminal amino groups in the adsorption mechanism of amino acids on hydrated metal oxides. The excellent agreement between computation and experiment for this amino acid opens the doors to the exploration of the interaction free energies for other moderately complex bionano systems.

Published
2024
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29. European Materials Modelling Council

Author

Adamovic, Nadja, Asinari, Pietro, Goldbeck, Gerhard, Hashibon, Adham, Hermansson, Kersti, Hristova-Bogaerds, Denka, Koopmans, Rudolf, Verbrugge, Tom, Wimmer, Erich, Mason, Paul, editor, Fisher, Charles R., editor, Glamm, Ryan, editor, Manuel, Michele V., editor, Schmitz, Georg J., editor, Singh, Amarendra K., editor, and Strachan, Alejandro, editor

Published
2017
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36. Water in Crystals : A Database for ML and a Knowledge Base for Vibrational Prediction

Author

Kullgren, Jolla, Röckert, Andreas, Hermansson, Kersti, Kullgren, Jolla, Röckert, Andreas, and Hermansson, Kersti

Abstract

Hydrate crystals are excellent reference systems to learnaboutaqueous systems. We have created a database of density functionaltheory (DFT)-optimized (optPBE-vdW) structures and vibrational frequenciesfor 101 crystalline hydrate and hydroxide bulk systems and over 300unique oscillators and use it to explore and discuss the tradeoffbetween prediction accuracy and insight. Starting from a machine-learninggeometrical descriptor, we gradually include more physics/chemistryflavor in the descriptor and examine how the frequency predictionpower varies. The most accurate models are the machine-learned model(of modest insight) and a physically motivated model containing theelectric field and field gradient. Furthermore, detailed comparisonswith experimental correlations show that, where available data exists,our DFT results largely overlap with the experiment. A small blind-testshowed that our machine-learned (ML) descriptor model can be usedto predict experimental vibrational frequencies based only on theexperimental structures and our best-regressed model, with encouragingresults.

Published
2023
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37. Origin of the Hydrophobic Behaviour of Hydrophilic CeO2

Author

Agosta, Lorenzo, Arismendi-Arrieta, Daniel, Dzugutov, Mikhail, Hermansson, Kersti, Agosta, Lorenzo, Arismendi-Arrieta, Daniel, Dzugutov, Mikhail, and Hermansson, Kersti

Abstract

The nature of the hydrophobicity found in rare-earth oxides is intriguing. The CeO2 (100) surface, despite its strongly hydrophilic nature, exhibits hydrophobic behaviour when immersed in water. In order to understand this puzzling and counter-intuitive effect we performed a detailed analysis of the water structure and dynamics. We report here an ab-initio molecular dynamics simulation (AIMD) study which demonstrates that the first water layer, in immediate contact with the hydroxylated CeO2 surface, is responsible for the effect behaving as a hydrophobic interface with respect to the rest of the liquid water. The hydrophobicity is manifested in several ways: a considerable diffusion enhancement of the confined liquid water as compared with bulk water at the same thermodynamic condition, a weak adhesion energy and few H-bonds above the hydrophobic water layer, which may also sustain a water droplet. These findings introduce a new concept in water/rare-earth oxide interfaces: hydrophobicity mediated by specific water patterns on a hydrophilic surface.

Published
2023
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38. A New Mars-van Krevelen Mechanism for CO Oxidation on a Ti-Decorated MXene

Author

Zhang, Xilin, Peng, Qianqian, Chen, Lu, Lu, Zhansheng, Yang, Zongxian, Hermansson, Kersti, Zhang, Xilin, Peng, Qianqian, Chen, Lu, Lu, Zhansheng, Yang, Zongxian, and Hermansson, Kersti

Abstract

First-principles computations are performed to investigate the catalytic oxidation of CO on a Ti-decorated Cr2TiC2O2 MXene monolayer, through comprehensive analysis of charge transfer, electronic density of states, and charge density difference of the interacting systems. By comparing the reaction energy barriers, it is found that, rather than the traditional Langmuir-Hinshelwood, Eley-Rideal, and Mars-van Krevelen (MvK) mechanisms, the CO oxidation favours a new variant of the MvK mechanism, in which the anchored Ti atom activates the surface oxygen to spill over from the substrate and take part in the CO oxidation. This work highlights the importance of activating the surface oxygen atoms of MXene by foreign metal atoms to improve the catalytic activity, and suggests that further studies into the new MvK mechanism for CO oxidation may prove worthwhile.

Published
2023
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39. H2O2(s) and H2O22H2O(s) crystals compared with ices : DFT functional assessment and D3 analysis

Author

Arismendi Arrieta, Daniel Jose, Sen, Anik, Eriksson, Anders, Broqvist, Peter, Kullgren, Jolla, Hermansson, Kersti, Arismendi Arrieta, Daniel Jose, Sen, Anik, Eriksson, Anders, Broqvist, Peter, Kullgren, Jolla, and Hermansson, Kersti

Abstract

The H2O and H2O2 molecules resemble each other in a multitude of ways as has been noted in the literature. Here, we present density functional theory (DFT) calculations for the H2O2(s) and H2O2·2H2O(s) crystals and make selected comparisons with ice polymorphs. The performance of a number of dispersion-corrected density functionals—both self-consistent and a posteriori ones—are assessed, and we give special attention to the D3 correction and its effects. The D3 correction to the lattice energies is large: for H2O2(s) the D3 correction constitutes about 25% of the lattice energy using PBE, much more for RPBE, much less for SCAN, and it primarily arises from non-H-bonded interactions out to about 5 Å.The large D3 corrections to the lattice energies are likely a consequence of several effects: correction for missing dispersion interaction, the ability of D3 to capture and correct various other kinds of limitations built into the underlying DFT functionals, and finally some degree of cell-contraction-induced polarization enhancement. We find that the overall best-performing functionals of the twelve examined are optPBEvdW and RPBE-D3. Comparisons with DFT assessments for ices in the literature show that where the same methods have been used, the assessments largely agree.

Published
2023
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44. Supercooled liquid-like dynamics in water near a fully hydrated titania surface: Decoupling of rotational and translational diffusion.

Author

Agosta, Lorenzo, Dzugutov, Mikhail, and Hermansson, Kersti

Subjects
ROTATIONAL diffusion, SUPERCOOLED liquids, SURFACE diffusion, GLASS transitions, KIRKENDALL effect, MOLECULAR dynamics
Abstract

We report an ab initio molecular dynamics (MD) simulation investigating the effect of a fully hydrated surface of TiO2 on the water dynamics. It is found that the universal relation between the rotational and translational diffusion characteristics of bulk water is broken in the water layers near the surface with the rotational diffusion demonstrating progressive retardation relative to the translational diffusion when approaching the surface. This kind of rotation–translation decoupling has so far only been observed in the supercooled liquids approaching glass transition, and its observation in water at a normal liquid temperature is of conceptual interest. This finding is also of interest for the application-significant studies of the water interaction with fully hydrated nanoparticles. We note that this is the first observation of rotation–translation decoupling in an ab initio MD simulation of water. [ABSTRACT FROM AUTHOR]

Published
2021
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46. The water/ceria(111) interface: Computational overview and new structures.

Author

Röckert, Andreas, Kullgren, Jolla, Broqvist, Peter, Alwan, Seif, and Hermansson, Kersti

Subjects
DENSITY functional theory, THIN films, WATER
Abstract

Thin film structures of water on the CeO2(111) surface for coverages between 0.5 and 2.0 water monolayers have been optimized and analyzed using density functional theory (optPBE-vdW functional). We present a new 1.0 ML structure that is both the lowest in energy published and features a hydrogen-bond network extending the surface in one-dimension, contrary to what has been found in the literature, and contrary to what has been expected due to the large bulk ceria cell dimension. The adsorption energies for the monolayer and multilayered water structures agree well with experimental temperature programmed desorption results from the literature, and we discuss the stability window of CeO2(111) surfaces covered with 0.5–2.0 ML of water. [ABSTRACT FROM AUTHOR]

Published
2020
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47. Origin of the Hydrophobic Behaviour of Hydrophilic CeO2.

Author

Agosta, Lorenzo, Arismendi‐Arrieta, Daniel, Dzugutov, Mikhail, and Hermansson, Kersti

Subjects
MOLECULAR dynamics, HYDROPHILIC surfaces, CERIUM oxides, WATER analysis
Abstract

The nature of the hydrophobicity found in rare‐earth oxides is intriguing. The CeO2 (100) surface, despite its strongly hydrophilic nature, exhibits hydrophobic behaviour when immersed in water. In order to understand this puzzling and counter‐intuitive effect we performed a detailed analysis of the confined water structure and dynamics. We report here an ab‐initio molecular dynamics simulation (AIMD) study which demonstrates that the first adsorbed water layer, in immediate contact with the hydroxylated CeO2 surface, generates a hydrophobic interface with respect to the rest of the liquid water. The hydrophobicity is manifested in several ways: a considerable diffusion enhancement of the confined liquid water as compared with bulk water at the same thermodynamic condition, a weak adhesion energy and few H‐bonds above the hydrophobic water layer, which may also sustain a water droplet. These findings introduce a new concept in water/rare‐earth oxide interfaces: hydrophobicity mediated by specific water patterns on a hydrophilic surface. [ABSTRACT FROM AUTHOR]

Published
2023
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48. Origin of the Hydrophobic Behaviour of Hydrophilic CeO2.

Author

Agosta, Lorenzo, Arismendi‐Arrieta, Daniel, Dzugutov, Mikhail, and Hermansson, Kersti

Subjects
MOLECULAR dynamics, HYDROPHILIC surfaces, CERIUM oxides, WATER analysis
Abstract

The nature of the hydrophobicity found in rare‐earth oxides is intriguing. The CeO2 (100) surface, despite its strongly hydrophilic nature, exhibits hydrophobic behaviour when immersed in water. In order to understand this puzzling and counter‐intuitive effect we performed a detailed analysis of the confined water structure and dynamics. We report here an ab‐initio molecular dynamics simulation (AIMD) study which demonstrates that the first adsorbed water layer, in immediate contact with the hydroxylated CeO2 surface, generates a hydrophobic interface with respect to the rest of the liquid water. The hydrophobicity is manifested in several ways: a considerable diffusion enhancement of the confined liquid water as compared with bulk water at the same thermodynamic condition, a weak adhesion energy and few H‐bonds above the hydrophobic water layer, which may also sustain a water droplet. These findings introduce a new concept in water/rare‐earth oxide interfaces: hydrophobicity mediated by specific water patterns on a hydrophilic surface. [ABSTRACT FROM AUTHOR]

Published
2023
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49. A Roadmap for Transforming Research to Invent the Batteries of the Future Designed within the European Large Scale Research Initiative BATTERY 2030+

Author

Amici, Julia, Asinari, Pietro, Ayerbe, Elixabete, Barboux, Philippe, Bayle-Guillemaud, Pascale, Behm, R. Juergen, Berecibar, Maitane, Berg, Erik, Bhowmik, Arghya, Bodoardo, Silvia, Castelli, Ivano E., Cekic-Laskovic, Isidora, Christensen, Rune, Clark, Simon, Diehm, Ralf, Dominko, Robert, Fichtner, Maximilian, Franco, Alejandro A., Grimaud, Alexis, Guillet, Nicolas, Hahlin, Maria, Hartmann, Sarah, Heiries, Vincent, Hermansson, Kersti, Heuer, Andreas, Jana, Saibal, Jabbour, Lara, Kallo, Josef, Latz, Arnulf, Lorrmann, Henning, Lovvik, Ole Martin, Lyonnard, Sandrine, Meeus, Marcel, Paillard, Elie, Perraud, Simon, Placke, Tobias, Punckt, Christian, Raccurt, Olivier, Ruhland, Janna, Sheridan, Edel, Stein, Helge, Tarascon, Jean-Marie, Trapp, Victor, Vegge, Tejs, Weil, Marcel, Wenzel, Wolfgang, Winter, Martin, Wolf, Andreas, Edström, Kristina, Amici, Julia, Asinari, Pietro, Ayerbe, Elixabete, Barboux, Philippe, Bayle-Guillemaud, Pascale, Behm, R. Juergen, Berecibar, Maitane, Berg, Erik, Bhowmik, Arghya, Bodoardo, Silvia, Castelli, Ivano E., Cekic-Laskovic, Isidora, Christensen, Rune, Clark, Simon, Diehm, Ralf, Dominko, Robert, Fichtner, Maximilian, Franco, Alejandro A., Grimaud, Alexis, Guillet, Nicolas, Hahlin, Maria, Hartmann, Sarah, Heiries, Vincent, Hermansson, Kersti, Heuer, Andreas, Jana, Saibal, Jabbour, Lara, Kallo, Josef, Latz, Arnulf, Lorrmann, Henning, Lovvik, Ole Martin, Lyonnard, Sandrine, Meeus, Marcel, Paillard, Elie, Perraud, Simon, Placke, Tobias, Punckt, Christian, Raccurt, Olivier, Ruhland, Janna, Sheridan, Edel, Stein, Helge, Tarascon, Jean-Marie, Trapp, Victor, Vegge, Tejs, Weil, Marcel, Wenzel, Wolfgang, Winter, Martin, Wolf, Andreas, and Edström, Kristina

Abstract

This roadmap presents the transformational research ideas proposed by "BATTERY 2030+," the European large-scale research initiative for future battery chemistries. A "chemistry-neutral" roadmap to advance battery research, particularly at low technology readiness levels, is outlined, with a time horizon of more than ten years. The roadmap is centered around six themes: 1) accelerated materials discovery platform, 2) battery interface genome, with the integration of smart functionalities such as 3) sensing and 4) self-healing processes. Beyond chemistry related aspects also include crosscutting research regarding 5) manufacturability and 6) recyclability. This roadmap should be seen as an enabling complement to the global battery roadmaps which focus on expected ultrahigh battery performance, especially for the future of transport. Batteries are used in many applications and are considered to be one technology necessary to reach the climate goals. Currently the market is dominated by lithium-ion batteries, which perform well, but despite new generations coming in the near future, they will soon approach their performance limits. Without major breakthroughs, battery performance and production requirements will not be sufficient to enable the building of a climate-neutral society. Through this "chemistry neutral" approach a generic toolbox transforming the way batteries are developed, designed and manufactured, will be created.

Published
2022
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50. Implications of the BATTERY 2030+ AI-Assisted Toolkit on Future Low-TRL Battery Discoveries and Chemistries

Author

Bhowmik, Arghya, Berecibar, Maitane, Casas-Cabanas, Montse, Csanyi, Gabor, Dominko, Robert, Hermansson, Kersti, Palacin, M. Rosa, Stein, Helge S., Vegge, Tejs, Bhowmik, Arghya, Berecibar, Maitane, Casas-Cabanas, Montse, Csanyi, Gabor, Dominko, Robert, Hermansson, Kersti, Palacin, M. Rosa, Stein, Helge S., and Vegge, Tejs

Abstract

BATTERY 2030+ targets the development of a chemistry neutral platform for accelerating the development of new sustainable high-performance batteries. Here, a description is given of how the AI-assisted toolkits and methodologies developed in BATTERY 2030+ can be transferred and applied to representative examples of future battery chemistries, materials, and concepts. This perspective highlights some of the main scientific and technological challenges facing emerging low-technology readiness level (TRL) battery chemistries and concepts, and specifically how the AI-assisted toolkit developed within BIG-MAP and other BATTERY 2030+ projects can be applied to resolve these. The methodological perspectives and challenges in areas like predictive long time- and length-scale simulations of multi-species systems, dynamic processes at battery interfaces, deep learned multi-scaling and explainable AI, as well as AI-assisted materials characterization, self-driving labs, closed-loop optimization, and AI for advanced sensing and self-healing are introduced. A description is given of tools and modules can be transferred to be applied to a select set of emerging low-TRL battery chemistries and concepts covering multivalent anodes, metal-sulfur/oxygen systems, non-crystalline, nano-structured and disordered systems, organic battery materials, and bulk vs. interface-limited batteries.

Published
2022
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