Your search keyword '"Head‐Gordon, Teresa"' showing total 239 results

1. Near equivalence of polarizability and bond order flux metrics for describing covalent bond rearrangements

Author

Kim, Lukas and Head-Gordon, Teresa

Subjects

Chemical Sciences, Physical Chemistry, Theoretical and Computational Chemistry, Chemical Physics

Abstract

Identification of the breaking point for the chemical bond is essential for our understanding of chemical reactivity. The current consensus is that a point of maximal electron delocalization along the bonding axis separates the different bonding regimes of reactants and products. This maximum transition point has been investigated previously through the total position spread and the bond-parallel components of the static polarizability tensor for describing covalent bond breaking. In this paper, we report that the first-order change of the Wiberg and Mayer bond index with respect to the reaction coordinate, the bond flux, is similarly maximized and is nearly equivalent with the bond breaking points determined by the bond-parallel polarizability. We investigate the similarites and differences between the two bonding metrics for breaking the nitrogen triple bond, twisting around the ethene double bond, and a set of prototypical reactions in the hydrogen combustion reaction network. The Wiberg-Mayer bond flux provides a simpler approach to calculating the point of bond dissociation and formation and can yield greater chemical insight through bond specific information for certain reactions where multiple bond changes are operative.

Published

2024

2. Analytical ab initio hessian from a deep learning potential for transition state optimization.

Author

Yuan, Eric, Kumar, Anup, Guan, Xingyi, Hermes, Eric, Rosen, Andrew, Zádor, Judit, Head-Gordon, Teresa, and Blau, Samuel

Abstract

Identifying transition states-saddle points on the potential energy surface connecting reactant and product minima-is central to predicting kinetic barriers and understanding chemical reaction mechanisms. In this work, we train a fully differentiable equivariant neural network potential, NewtonNet, on thousands of organic reactions and derive the analytical Hessians. By reducing the computational cost by several orders of magnitude relative to the density functional theory (DFT) ab initio source, we can afford to use the learned Hessians at every step for the saddle point optimizations. We show that the full machine learned (ML) Hessian robustly finds the transition states of 240 unseen organic reactions, even when the quality of the initial guess structures are degraded, while reducing the number of optimization steps to convergence by 2-3× compared to the quasi-Newton DFT and ML methods. All data generation, NewtonNet model, and ML transition state finding methods are available in an automated workflow.

Published

2024

3. Simple and Accurate One-Body Energy and Dipole Moment Surfaces for Water and Beyond

Author

Sami, Selim, LaCour, R Allen, Heindel, Joseph P, and Head-Gordon, Teresa

Subjects

Physical Sciences, Chemical Sciences, Physical Chemistry, Chemical sciences, Physical sciences

Abstract

Water is often the testing ground for new, advanced force fields. While advanced functional forms for intermolecular interactions have been integral to the development of accurate water models, less attention has been paid to a transferable model for intramolecular valence terms. In this work, we present a one-body energy and dipole moment surface model, named 1B-UCB, that is simple yet accurate and can be feasibly adapted for both standard and advanced potentials. 1B-UCB for water is comparable in accuracy to those with much more complex functional forms, despite having drastically fewer parameters. The parametrization protocol has been implemented as part of the Q-Force automated workflow and requires only a quantum mechanical Hessian calculation as reference data, hence allowing it to be easily extended to a variety of molecular systems beyond water, which we demonstrate on a selection of small molecules with different symmetries.

Published

2024

4. A curated rotamer library for common post-translational modifications of proteins.

Author

Zhang, Oufan, Naik, Shubhankar, Liu, Zi, Forman-Kay, Julie, and Head-Gordon, Teresa

Subjects

Protein Processing, Post-Translational, Proteins, Databases, Protein, Intrinsically Disordered Proteins, Algorithms, Protein Folding, Monte Carlo Method, Protein Conformation, Amino Acids, Software

Abstract

MOTIVATION: Sidechain rotamer libraries of the common amino acids of a protein are useful for folded protein structure determination and for generating ensembles of intrinsically disordered proteins (IDPs). However, much of protein function is modulated beyond the translated sequence through the introduction of post-translational modifications (PTMs). RESULTS: In this work, we have provided a curated set of side chain rotamers for the most common PTMs derived from the RCSB PDB database, including phosphorylated, methylated, and acetylated sidechains. Our rotamer libraries improve upon existing methods such as SIDEpro, Rosetta, and AlphaFold3 in predicting the experimental structures for PTMs in folded proteins. In addition, we showcase our PTM libraries in full use by generating ensembles with the Monte Carlo Side Chain Entropy (MCSCE) for folded proteins, and combining MCSCE with the Local Disordered Region Sampling algorithms within IDPConformerGenerator for proteins with intrinsically disordered regions. AVAILABILITY AND IMPLEMENTATION: The codes for dihedral angle computations and library creation are available at https://github.com/THGLab/ptm_sc.git.

Published

2024

5. The role of charge in microdroplet redox chemistry

Author

Heindel, Joseph P, LaCour, R Allen, and Head-Gordon, Teresa

Subjects

Chemical Sciences, Physical Chemistry, Theoretical and Computational Chemistry

Abstract

In charged water microdroplets, which occur in nature or in the lab upon ultrasonication or in electrospray processes, the thermodynamics for reactive chemistry can be dramatically altered relative to the bulk phase. Here, we provide a theoretical basis for the observation of accelerated chemistry by simulating water droplets of increasing charge imbalance to create redox agents such as hydroxyl and hydrogen radicals and solvated electrons. We compute the hydration enthalpy of OH- and H+ that controls the electron transfer process, and the corresponding changes in vertical ionization energy and vertical electron affinity of the ions, to create OH• and H• reactive species. We find that at ~ 20 - 50% of the Rayleigh limit of droplet charge the hydration enthalpy of both OH- and H+ have decreased by >50 kcal/mol such that electron transfer becomes thermodynamically favorable, in correspondence with the more favorable vertical electron affinity of H+ and the lowered vertical ionization energy of OH-. We provide scaling arguments that show that the nanoscale calculations and conclusions extend to the experimental microdroplet length scale. The relevance of the droplet charge for chemical reactivity is illustrated for the formation of H2O2, and has clear implications for other redox reactions observed to occur with enhanced rates in microdroplets.

Published

2024

6. Local Disordered Region Sampling (LDRS) for ensemble modeling of proteins with experimentally undetermined or low confidence prediction segments.

Author

Liu, Zi, Teixeira, João, Zhang, Oufan, Tsangaris, Thomas, Li, Jie, Gradinaru, Claudiu, Forman-Kay, Julie, and Head-Gordon, Teresa

Subjects

Software, Intrinsically Disordered Proteins, Gene Library, Membrane Proteins, Documentation

Abstract

SUMMARY: The Local Disordered Region Sampling (LDRS, pronounced loaders) tool is a new module developed for IDPConformerGenerator, a previously validated approach to model intrinsically disordered proteins (IDPs). The IDPConformerGenerator LDRS module provides a method for generating all-atom conformations of intrinsically disordered protein regions at N- and C-termini of and in loops or linkers between folded regions of an existing protein structure. These disordered elements often lead to missing coordinates in experimental structures or low confidence in predicted structures. Requiring only a pre-existing PDB or mmCIF formatted structural template of the protein with missing coordinates or with predicted confidence scores and its full-length primary sequence, LDRS will automatically generate physically meaningful conformational ensembles of the missing flexible regions to complete the full-length protein. The capabilities of the LDRS tool of IDPConformerGenerator include modeling phosphorylation sites using enhanced Monte Carlo-Side Chain Entropy, transmembrane proteins within an all-atom bilayer, and multi-chain complexes. The modeling capacity of LDRS capitalizes on the modularity, the ability to be used as a library and via command-line, and the computational speed of the IDPConformerGenerator platform. AVAILABILITY AND IMPLEMENTATION: The LDRS module is part of the IDPConformerGenerator modeling suite, which can be downloaded from GitHub at https://github.com/julie-forman-kay-lab/IDPConformerGenerator. IDPConformerGenerator is written in Python3 and works on Linux, Microsoft Windows, and Mac OS versions that support DSSP. Users can utilize LDRSs Python API for scripting the same way they can use any part of IDPConformerGenerators API, by importing functions from the idpconfgen.ldrs_helper library. Otherwise, LDRS can be used as a command line interface application within IDPConformerGenerator. Full documentation is available within the command-line interface as well as on IDPConformerGenerators official documentation pages (https://idpconformergenerator.readthedocs.io/en/latest/).

Published

2023

7. ChatGPT Research Group for Optimizing the Crystallinity of MOFs and COFs.

Author

Zheng, Zhiling, Zhang, Oufan, Nguyen, Ha, Rampal, Nakul, Alawadhi, Ali, Rong, Zichao, Head-Gordon, Teresa, Borgs, Christian, Chayes, Jennifer, and Yaghi, Omar

Abstract

We leveraged the power of ChatGPT and Bayesian optimization in the development of a multi-AI-driven system, backed by seven large language model-based assistants and equipped with machine learning algorithms, that seamlessly orchestrates a multitude of research aspects in a chemistry laboratory (termed the ChatGPT Research Group). Our approach accelerated the discovery of optimal microwave synthesis conditions, enhancing the crystallinity of MOF-321, MOF-322, and COF-323 and achieving the desired porosity and water capacity. In this system, human researchers gained assistance from these diverse AI collaborators, each with a unique role within the laboratory environment, spanning strategy planning, literature search, coding, robotic operation, labware design, safety inspection, and data analysis. Such a comprehensive approach enables a single researcher working in concert with AI to achieve productivity levels analogous to those of an entire traditional scientific team. Furthermore, by reducing human biases in screening experimental conditions and deftly balancing the exploration and exploitation of synthesis parameters, our Bayesian search approach precisely zeroed in on optimal synthesis conditions from a pool of 6 million within a significantly shortened time scale. This work serves as a compelling proof of concept for an AI-driven revolution in the chemistry laboratory, painting a future where AI becomes an efficient collaborator, liberating us from routine tasks to focus on pushing the boundaries of innovation.

Published

2023

8. The Energetic Origins of Pi-Pi Contacts in Proteins.

Author

Liu, Meili, Pujal, Leila, Loipersberger, Matthias, Tsanai, Maria, Vernon, Robert, Forman-Kay, Julie, Heidar-Zadeh, Farnaz, Head-Gordon, Martin, Head-Gordon, Teresa, and Carter-Fenk, Kevin

Abstract

Accurate potential energy models of proteins must describe the many different types of noncovalent interactions that contribute to a proteins stability and structure. Pi-pi contacts are ubiquitous structural motifs in all proteins, occurring between aromatic and nonaromatic residues and play a nontrivial role in protein folding and in the formation of biomolecular condensates. Guided by a geometric criterion for isolating pi-pi contacts from classical molecular dynamics simulations of proteins, we use quantum mechanical energy decomposition analysis to determine the molecular interactions that stabilize different pi-pi contact motifs. We find that neutral pi-pi interactions in proteins are dominated by Pauli repulsion and London dispersion rather than repulsive quadrupole electrostatics, which is central to the textbook Hunter-Sanders model. This results in a notable lack of variability in the interaction profiles of neutral pi-pi contacts even with extreme changes in the dielectric medium, explaining the prevalence of pi-stacked arrangements in and between proteins. We also find interactions involving pi-containing anions and cations to be extremely malleable, interacting like neutral pi-pi contacts in polar media and like typical ion-pi interactions in nonpolar environments. Like-charged pairs such as arginine-arginine contacts are particularly sensitive to the polarity of their immediate surroundings and exhibit canonical pi-pi stacking behavior only if the interaction is mediated by environmental effects, such as aqueous solvation.

Published

2023

9. Greater transferability and accuracy of norm-conserving pseudopotentials using nonlinear core corrections

Author

Li, Wan-Lu, Chen, Kaixuan, Rossomme, Elliot, Head-Gordon, Martin, and Head-Gordon, Teresa

Subjects

Chemical Sciences, Physical Chemistry, Chemical sciences

Abstract

We present an investigation into the transferability of pseudopotentials (PPs) with a nonlinear core correction (NLCC) using the Goedecker, Teter, and Hutter (GTH) protocol across a range of pure GGA, meta-GGA and hybrid functionals, and their impact on thermochemical and non-thermochemical properties. The GTH-NLCC PP for the PBE density functional demonstrates remarkable transferability to the PBE0 and ωB97X-V exchange-correlation functionals, and relative to no NLCC, improves agreement significantly for thermochemical benchmarks compared to all-electron calculations. On the other hand, the B97M-rV meta-GGA functional performs poorly with the PBE-derived GTH-NLCC PP, which is mitigated by reoptimizing the NLCC parameters for this specific functional. The findings reveal that atomization energies exhibit the greatest improvements from use of the NLCC, which thus provides an important correction needed for covalent interactions relevant to applications involving chemical reactivity. Finally we test the NLCC-GTH PPs when combined with medium-size TZV2P molecularly optimized (MOLOPT) basis sets which are typically utilized in condensed phase simulations, and show that they lead to consistently good results when compared to all-electron calculations for atomization energies, ionization potentials, barrier heights, and non-covalent interactions, but lead to somewhat larger errors for electron affinities.

Published

2023

10. Using Diffusion Maps to Analyze Reaction Dynamics for a Hydrogen Combustion Benchmark Dataset

Author

Ko, Taehee, Heindel, Joseph P, Guan, Xingyi, Head-Gordon, Teresa, Williams-Young, David B, and Yang, Chao

Subjects

Chemical Sciences, Physical Chemistry, Affordable and Clean Energy, Theoretical and Computational Chemistry, Biochemistry and Cell Biology, Computer Software, Chemical Physics, Physical chemistry, Theoretical and computational chemistry

Abstract

We use local diffusion maps to assess the quality of two types of collective variables (CVs) for a recently published hydrogen combustion benchmark dataset1 that contains ab initio molecular dynamics (MD) trajectories and normal modes along minimum energy paths. This approach was recently advocated in2 for assessing CVs and analyzing reactions modeled by classical MD simulations. We report the effectiveness of this approach to molecular systems modeled by quantum ab initio MD. In addition to assessing the quality of CVs, we also use global diffusion maps to perform committor analysis as proposed in.2 We show that the committor function obtained from the global diffusion map allows us to identify transition regions of interest in several hydrogen combustion reaction channels.

Published

2023

11. Learning Correlations between Internal Coordinates to Improve 3D Cartesian Coordinates for Proteins.

Author

Zhang, Oufan, Lee, Seokyoung, Namini, Ashley, Liu, Zi, Teixeira, João, Forman-Kay, Julie, Head-Gordon, Teresa, and LI, JIE

Subjects

Proteins, Algorithms, Machine Learning

Abstract

We consider a generic representation problem of internal coordinates (bond lengths, valence angles, and dihedral angles) and their transformation to 3-dimensional Cartesian coordinates of a biomolecule. We show that the internal-to-Cartesian process relies on correctly predicting chemically subtle correlations among the internal coordinates themselves, and learning these correlations increases the fidelity of the Cartesian representation. We developed a machine learning algorithm, Int2Cart, to predict bond lengths and bond angles from backbone torsion angles and residue types of a protein, which allows reconstruction of protein structures better than using fixed bond lengths and bond angles or a static library method that relies on backbone torsion angles and residue types in a local environment. The method is able to be used for structure validation, as we show that the agreement between Int2Cart-predicted bond geometries and those from an AlphaFold 2 model can be used to estimate model quality. Additionally, by using Int2Cart to reconstruct an IDP ensemble, we are able to decrease the clash rate during modeling. The Int2Cart algorithm has been implemented as a publicly accessible python package at https://github.com/THGLab/int2cart.

Published

2023

12. How thermal fluctuations influence the function of the FeMo cofactor in nitrogenase enzymes

Author

Li, Wan-Lu, Li, Yong, Li, Jun, and Head-Gordon, Teresa

Abstract

The catalytic mechanism of N2 fixation by nitrogenase remains unresolved in how the strong N≡N bond is activated and why the reductive elimination of H2 is required. Here, we use density functional theory and physiologically relevant thermal simulations to elucidate the mechanism of the complete nitrogenase catalytic cycle. Over the accumulation of four reducing equivalents, we find that protons and electrons transfer to the FeMo cofactor to weaken and break its bridge Fe–S bond, leading to temporary H2S formation that exposes the Fe sites to weakly bind N2. Remarkably, we find that subsequent H2 formation is responsible for chemical activation to an N=N double bond accompanied by a low barrier for H2 release. We emphasize that finite temperature effects smooth out mechanistic differences between DFT functionals observed at 0 K, thus leading to a consistent understanding as to why H formation is an obligatory step in N2 adsorption and activation.

Published

2023

13. The Good, the Bad, and the Ugly: Pseudopotential Inconsistency Errors in Molecular Applications of Density Functional Theory

Author

Rossomme, Elliot, Cunha, Leonardo A, Li, Wanlu, Chen, Kaixuan, McIsaac, Alexandra R, Head-Gordon, Teresa, and Head-Gordon, Martin

Subjects

Chemical Sciences, Physical Chemistry, CSD-47-SciDAC, CSD-46-All CSGB, Theoretical and Computational Chemistry, Biochemistry and Cell Biology, Computer Software, Chemical Physics, Physical chemistry, Theoretical and computational chemistry

Abstract

The pseudopotential (PP) approximation is one of the most common techniques in computational chemistry. Despite its long history, the development of custom PPs has not tracked with the explosion of different density functional approximations (DFAs). As a result, the use of PPs with exchange/correlation models for which they were not developed is widespread, although this practice is known to be theoretically unsound. The extent of PP inconsistency errors (PPIEs) associated with this practice has not been systematically explored across the types of energy differences commonly evaluated in chemical applications. We evaluate PPIEs for a number of PPs and DFAs across 196 chemically relevant systems of both transition-metal and main-group elements, as represented by the W4-11, TMC34, and S22 data sets. Near the complete basis set limit, these PPs are found to cleanly approach all-electron (AE) results for noncovalent interactions but introduce root-mean-squared errors (RMSEs) upwards of 15 kcal mol-1 into predictions of covalent bond energies for a number of popular DFAs. We achieve significant improvements through the use of empirical atom- and DFA-specific PP corrections, indicating considerable systematicity of the PPIEs. The results of this work have implications for chemical modeling in both molecular contexts and for DFA design, which we discuss.

Published

2023

14. M-Chem: a modular software package for molecular simulation that spans scientific domains

Author

Witek, Jagna, Heindel, Joseph P, Guan, Xingyi, Leven, Itai, Hao, Hongxia, Naullage, Pavithra, LaCour, Allen, Sami, Selim, Menger, MFSJ, Cofer-Shabica, D Vale, Berquist, Eric, Faraji, Shirin, Epifanovsky, Evgeny, and Head-Gordon, Teresa

Subjects

Bioengineering, Networking and Information Technology R&D (NITRD), Generic health relevance, Machine learning, force fields, molecular dynamics, QM, MM, simulation software, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural), Theoretical and Computational Chemistry, Chemical Physics

Abstract

We present a new software package called M-Chem that is designed from scratch in C++ and parallelized on shared-memory multi-core architectures to facilitate efficient molecular simulations. Currently, M-Chem is a fast molecular dynamics (MD) engine that supports the evaluation of energies and forces from two-body to many-body all-atom potentials, reactive force fields, coarse-grained models, combined quantum mechanics molecular mechanics (QM/MM) models, and external force drivers from machine learning, augmented by algorithms that are focused on gains in computational simulation times. M-Chem also includes a range of standard simulation capabilities including thermostats, barostats, multi-timestepping, and periodic cells, as well as newer methods such as fast extended Lagrangians and high quality electrostatic potential generation. At present M-Chem is a developer friendly environment in which we encourage new software contributors from diverse fields to build their algorithms, models, and methods in our modular framework. The long-term objective of M-Chem is to create an interdisciplinary platform for computational methods with applications ranging from biomolecular simulations, reactive chemistry, to materials research.

Published

2023

15. Learning to evolve structural ensembles of unfolded and disordered proteins using experimental solution data.

Author

Zhang, Oufan, Haghighatlari, Mojtaba, LI, JIE, Liu, Zi, Namini, Ashley, Teixeira, João, Forman-Kay, Julie, and Head-Gordon, Teresa

Subjects

Nuclear Magnetic Resonance, Biomolecular, Proteins, Magnetic Resonance Spectroscopy, Protein Conformation, Intrinsically Disordered Proteins

Abstract

The structural characterization of proteins with a disorder requires a computational approach backed by experiments to model their diverse and dynamic structural ensembles. The selection of conformational ensembles consistent with solution experiments of disordered proteins highly depends on the initial pool of conformers, with currently available tools limited by conformational sampling. We have developed a Generative Recurrent Neural Network (GRNN) that uses supervised learning to bias the probability distributions of torsions to take advantage of experimental data types such as nuclear magnetic resonance J-couplings, nuclear Overhauser effects, and paramagnetic resonance enhancements. We show that updating the generative model parameters according to the reward feedback on the basis of the agreement between experimental data and probabilistic selection of torsions from learned distributions provides an alternative to existing approaches that simply reweight conformers of a static structural pool for disordered proteins. Instead, the biased GRNN, DynamICE, learns to physically change the conformations of the underlying pool of the disordered protein to those that better agree with experiments.

Published

2023

16. An in-silico NMR laboratory for nuclear magnetic shieldings computed via finite fields: Exploring nucleus-specific renormalizations of MP2 and MP3

Author

Wong, Jonathan, Ganoe, Brad, Liu, Xiao, Neudecker, Tim, Lee, Joonho, Liang, Jiashu, Wang, Zhe, Li, Jie, Rettig, Adam, Head-Gordon, Teresa, and Head-Gordon, Martin

Subjects

Physical Sciences, Chemical Sciences, Physical Chemistry, Engineering, Chemical Physics, Chemical sciences, Physical sciences

Abstract

We developed and implemented a method-independent, fully numerical, finite difference approach to calculating nuclear magnetic resonance shieldings, using gauge-including atomic orbitals. The resulting capability can be used to explore non-standard methods, given only the energy as a function of finite-applied magnetic fields and nuclear spins. For example, standard second-order Møller-Plesset theory (MP2) has well-known efficacy for 1H and 13C shieldings and known limitations for other nuclei such as 15N and 17O. It is, therefore, interesting to seek methods that offer good accuracy for 15N and 17O shieldings without greatly increased compute costs, as well as exploring whether such methods can further improve 1H and 13C shieldings. Using a small molecule test set of 28 species, we assessed two alternatives: κ regularized MP2 (κ-MP2), which provides energy-dependent damping of large amplitudes, and MP2.X, which includes a variable fraction, X, of third-order correlation (MP3). The aug-cc-pVTZ basis was used, and coupled cluster with singles and doubles and perturbative triples [CCSD(T)] results were taken as reference values. Our κ-MP2 results reveal significant improvements over MP2 for 13C and 15N, with the optimal κ value being element-specific. κ-MP2 with κ = 2 offers a 30% rms error reduction over MP2. For 15N, κ-MP2 with κ = 1.1 provides a 90% error reduction vs MP2 and a 60% error reduction vs CCSD. On the other hand, MP2.X with a scaling factor of 0.6 outperformed CCSD for all heavy nuclei. These results can be understood as providing renormalization of doubles amplitudes to partially account for neglected triple and higher substitutions and offer promising opportunities for future applications.

Published

2023

17. Force Decomposition Analysis: A Method to Decompose Intermolecular Forces into Physically Relevant Component Contributions

Author

Aldossary, Abdulrahman, Gimferrer, Martí, Mao, Yuezhi, Hao, Hongxia, Das, Akshaya K, Salvador, Pedro, Head-Gordon, Teresa, and Head-Gordon, Martin

Subjects

Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural), Theoretical and Computational Chemistry

Abstract

Computational quantum chemistry can be more than just numerical experiments when methods are specifically adapted to investigate chemical concepts. One important example is the development of energy decomposition analysis (EDA) to reveal the physical driving forces behind intermolecular interactions. In EDA, typically the interaction energy from a good-quality density functional theory (DFT) calculation is decomposed into multiple additive components that unveil permanent and induced electrostatics, Pauli repulsion, dispersion, and charge-transfer contributions to noncovalent interactions. Herein, we formulate, implement, and investigate decomposing the forces associated with intermolecular interactions into the same components. The resulting force decomposition analysis (FDA) is potentially useful as a complement to the EDA to understand chemistry, while also providing far more information than an EDA for data analysis purposes such as training physics-based force fields. We apply the FDA based on absolutely localized molecular orbitals (ALMOs) to analyze interactions of water with sodium and chloride ions as well as in the water dimer. We also analyze the forces responsible for geometric changes in carbon dioxide upon adsorption onto (and activation by) gold and silver anions. We also investigate how the force components of an EDA-based force field for water clusters, namely MB-UCB, compare to those from force decomposition analysis.

Published

2023

18. The birth and evolution of solvated electrons in the water

Author

Novelli, Fabio, Chen, Kaixuan, Buchmann, Adrian, Ockelmann, Thorsten, Hoberg, Claudius, Head-Gordon, Teresa, and Havenith, Martina

Subjects

Chemical Sciences, Physical Chemistry, Theoretical and Computational Chemistry, Physical Sciences, Atomic, Molecular and Optical Physics, solvated electron, THz spectroscopy, ab initio MD, CSD-03-CPIMS-A, CSD-46-All CSGB

Abstract

The photo-induced radiolysis of water is an elementary reaction in biology and chemistry, forming solvated electrons, OH radicals, and hydronium cations on fast time scales. Here, we use an optical-pump terahertz-probe spectroscopy setup to trigger the photoionization of water molecules with optical laser pulses at ~400 nm and then time-resolve the transient solvent response with broadband terahertz (THz) fields with a ~90 fs time resolution. We observe three distinct spectral responses. The first is a positive broadband mode that can be attributed to an initial diffuse, delocalized electron with a radius of (22 ± 1) Å, which is short lived (

Published

2023

19. Highly Altered State of Proton Transport in Acid Pools in Charged Reverse Micelles

Author

Hao, Hongxia, Adams, Ellen M, Funke, Sarah, Schwaab, Gerhard, Havenith, Martina, and Head-Gordon, Teresa

Subjects

Chemical Sciences, Physical Chemistry, General Chemistry, Chemical sciences, Engineering

Abstract

Transport mechanisms of solvated protons of 1 M HCl acid pools, confined within reverse micelles (RMs) containing the negatively charged surfactant sodium bis(2-ethylhexyl) sulfosuccinate (NaAOT) or the positively charged cetyltrimethylammonium bromide (CTABr), are analyzed with reactive force field simulations to interpret dynamical signatures from TeraHertz absorption and dielectric relaxation spectroscopy. We find that the forward proton hopping events for NaAOT are further suppressed compared to a nonionic RM, while the Grotthuss mechanism ceases altogether for CTABr. We attribute the sluggish proton dynamics for both charged RMs as due to headgroup and counterion charges that expel hydronium and chloride ions from the interface and into the bulk interior, thereby increasing the pH of the acid pools relative to the nonionic RM. For charged NaAOT and CTABr RMs, the localization of hydronium near a counterion or conjugate base reduces the Eigen and Zundel configurations that enable forward hopping. Thus, localized oscillatory hopping dominates, an effect that is most extreme for CTABr in which the proton residence time increases dramatically such that even oscillatory hopping is slow.

Published

2023

20. Efficient Calculation of NMR Shielding Constants Using Composite Method Approximations and Locally Dense Basis Sets

Author

Liang, Jiashu, Wang, Zhe, Li, Jie, Wong, Jonathan, Liu, Xiao, Ganoe, Brad, Head-Gordon, Teresa, and Head-Gordon, Martin

Subjects

Theoretical and Computational Chemistry, Biochemistry and Cell Biology, Computer Software, Chemical Physics

Abstract

This paper presents a systematic study of applying composite method approximations with locally dense basis sets (LDBS) to efficiently calculate NMR shielding constants in small and medium-sized molecules. The pcSseg-n series of basis sets are shown to have similar accuracy to the pcS-n series when n ≥ 1 and can slightly reduce computational costs. We identify two different LDBS partition schemes that perform very effectively for density functional calculations. We select a large subset of the recent NS372 database containing 290 H, C, N, and O shielding values evaluated by reference methods on 106 molecules to carefully assess methods of the high, medium, and low computational costs to make practical recommendations. Our assessment covers conventional electronic structure methods (density functional theory and wave function) with global basis calculations, as well as their use in one of the satisfactory LDBS approaches, and a range of composite approaches, also with and without LDBS. Altogether 99 methods are evaluated. On this basis, we recommend different methods to reach three different levels of accuracy and time requirements across the four nuclei considered.

Published

2023

21. Highly Altered State of Proton Transport in Acid Pools in Charged Reverse Micelles

Author

Hao, Hongxia, Adams, Ellen M, Funke, Sarah, Schwaab, Gerhard, Havenith, Martina, and Head-Gordon, Teresa

Subjects

Chemical Sciences, General Chemistry, Chemical sciences, Engineering

Published

2023

22. Spontaneous Formation of Hydrogen Peroxide in Water Microdroplets

Author

Heindel, Joseph P, Hao, Hongxia, LaCour, R Allen, and Head-Gordon, Teresa

Subjects

Affordable and Clean Energy, Physical Sciences, Chemical Sciences

Abstract

There is accumulating evidence that many chemical reactions are accelerated by several orders of magnitude in micrometer-sized aqueous or organic liquid droplets compared to their corresponding bulk liquid phase. However, the molecular origin of the enhanced rates remains unclear as in the case of spontaneous appearance of 1 μM hydrogen peroxide in water microdroplets. In this Letter, we consider the range of ionization energies and whether interfacial electric fields of a microdroplet can feasibly overcome the high energy step from hydroxide ions (OH-) to hydroxyl radicals (OH•) in a primary H2O2 mechanism. We find that the vertical ionization energies (VIEs) of partially solvated OH- ions are greatly lowered relative to the average VIE in the bulk liquid, unlike the case of the Cl- anion which shows no reduction in the VIEs regardless of solvation environment. Overall reduced hydrogen-bonding and undercoordination of OH- are structural features that are more readily present at the air-water interface, where the energy scale for ionization can be matched by statistically probable electric field values.

Published

2022

23. IDPConformerGenerator: A Flexible Software Suite for Sampling the Conformational Space of Disordered Protein States

Author

Teixeira, João MC, Liu, Zi Hao, Namini, Ashley, Li, Jie, Vernon, Robert M, Krzeminski, Mickaël, Shamandy, Alaa A, Zhang, Oufan, Haghighatlari, Mojtaba, Yu, Lei, Head-Gordon, Teresa, and Forman-Kay, Julie D

Subjects

Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance, Bayes Theorem, Databases, Protein, Intrinsically Disordered Proteins, Protein Conformation, Protein Structure, Secondary, Software, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural), Theoretical and Computational Chemistry

Abstract

The power of structural information for informing biological mechanisms is clear for stable folded macromolecules, but similar structure-function insight is more difficult to obtain for highly dynamic systems such as intrinsically disordered proteins (IDPs) which must be described as structural ensembles. Here, we present IDPConformerGenerator, a flexible, modular open-source software platform for generating large and diverse ensembles of disordered protein states that builds conformers that obey geometric, steric, and other physical restraints on the input sequence. IDPConformerGenerator samples backbone phi (φ), psi (ψ), and omega (ω) torsion angles of relevant sequence fragments from loops and secondary structure elements extracted from folded protein structures in the RCSB Protein Data Bank and builds side chains from robust Monte Carlo algorithms using expanded rotamer libraries. IDPConformerGenerator has many user-defined options enabling variable fractional sampling of secondary structures, supports Bayesian models for assessing the agreement of IDP ensembles for consistency with experimental data, and introduces a machine learning approach to transform between internal and Cartesian coordinates with reduced error. IDPConformerGenerator will facilitate the characterization of disordered proteins to ultimately provide structural insights into these states that have key biological functions.

Published

2022

24. Words Matter: On the Debate over Free Speech, Inclusivity, and Academic Excellence

Author

Herbert, John M, Head-Gordon, Martin, Hratchian, Hrant P, Head-Gordon, Teresa, Amaro, Rommie E, Aspuru-Guzik, Alán, Hoffmann, Roald, Parish, Carol A, Payne, Christina M, and Van Voorhis, Troy

Subjects

Speech, Physical Sciences, Chemical Sciences

Published

2022

25. Optimizing the Solvent Reorganization Free Energy by Metal Substitution for Nanocage Catalysis

Author

Li, Wan-Lu, Hao, Hongxia, and Head-Gordon, Teresa

Subjects

nanocage catalysis, reorganization energy, electric field analysis, metal substitution, solvation, Inorganic Chemistry, Organic Chemistry, Chemical Engineering

Abstract

The supramolecular capsule Ga4L612- has been found to catalyze a number of important chemical reactions, but the close proximity of a poorly organized external solvent environment can serve as an impediment to the reaction chemistry. Using ab initio molecular dynamic calculations and electric field analyses, we find that metal substitution of indium for gallium lowers the total and electrostatic activation barriers by ∼3-4 kcal/mol in water solvent. Using an energy decomposition analysis of the interaction of water solvent with the metal vertices, we find that Pauli repulsion between the metal and water decreases, allowing the water coordination with the metal to increase, upon substitution of In for Ga. We therefore determine that the stabilization of the transition state is due to a better arrangement of water molecules around the metal vertices of In4L612- and provides a proof of concept of how to redesign the nanocage scaffold in order to reduce the solvent reorganization energy.

Published

2022

26. Evaporation of Water Nanodroplets on Heated Surfaces: Does Nano Matter?

Author

Pestana, Luis Ruiz and Head-Gordon, Teresa

Subjects

Physical Sciences, Classical Physics, nanodroplet, water, evaporation, molecular dynamics, kinetics, non-equilibrium, Nanoscience & Nanotechnology

Abstract

While experiments and continuum models have provided a relatively good understanding of the evaporation of macroscopic water droplets, elucidating how sessile nanodroplets evaporate is an open question critical for advancing nanotechnological applications where nanodroplets can play an essential role. Here, using molecular dynamics simulations, we find that evaporating nanodroplets, in contrast to their macroscopic counterparts, are not always in thermal equilibrium with the substrate and that the vapor concentration on the nanodroplet surface does not reach a steady state. As a result, the evaporative behavior of nanodroplets is significantly different. Regardless of hydrophobicity, nanodroplets do not follow conventional evaporation modes but instead exhibit dynamic wetting behavior characterized by huge, non-equilibrium, isovolumetric fluctuations in the contact angle and contact radius. For hydrophilic nanodroplets, the evaporation rate, controlled by the vapor concentration, decays exponentially over time. Hydrophobic nanodroplets follow stretched exponential kinetics arising from the slower thermalization with the substrate. The evaporative half-lifetime of the nanodroplets is directly related to the thermalization time scale and therefore increases monotonically with the hydrophobicity of the substrate. Finally, the evaporative flux profile along the nanodroplet surface is highly nonuniform but does not diverge at the contact line as the macroscopic continuum models predict.

Published

2022

27. Protein Dynamics to Define and Refine Disordered Protein Ensembles

Author

Naullage, Pavithra M, Haghighatlari, Mojtaba, Namini, Ashley, Teixeira, João MC, Li, Jie, Zhang, Oufan, Gradinaru, Claudiu C, Forman-Kay, Julie D, and Head-Gordon, Teresa

Subjects

Neurosciences, Underpinning research, 1.1 Normal biological development and functioning, Generic health relevance, Fluorescence Resonance Energy Transfer, Intrinsically Disordered Proteins, Nuclear Magnetic Resonance, Biomolecular, Protein Conformation, Protein Folding, src Homology Domains, Physical Sciences, Chemical Sciences, Engineering

Abstract

Intrinsically disordered proteins and unfolded proteins have fluctuating conformational ensembles that are fundamental to their biological function and impact protein folding, stability, and misfolding. Despite the importance of protein dynamics and conformational sampling, time-dependent data types are not fully exploited when defining and refining disordered protein ensembles. Here we introduce a computational framework using an elastic network model and normal-mode displacements to generate a dynamic disordered ensemble consistent with NMR-derived dynamics parameters, including transverse R2 relaxation rates and Lipari-Szabo order parameters (S2 values). We illustrate our approach using the unfolded state of the drkN SH3 domain to show that the dynamical ensembles give better agreement than a static ensemble for a wide range of experimental validation data including NMR chemical shifts, J-couplings, nuclear Overhauser effects, paramagnetic relaxation enhancements, residual dipolar couplings, hydrodynamic radii, single-molecule fluorescence Förster resonance energy transfer, and small-angle X-ray scattering.

Published

2022

28. A benchmark dataset for Hydrogen Combustion

Author

Guan, Xingyi, Das, Akshaya, Stein, Christopher J, Heidar-Zadeh, Farnaz, Bertels, Luke, Liu, Meili, Haghighatlari, Mojtaba, Li, Jie, Zhang, Oufan, Hao, Hongxia, Leven, Itai, Head-Gordon, Martin, and Head-Gordon, Teresa

Subjects

Physical Sciences, Chemical Sciences, Physical Chemistry, Affordable and Clean Energy

Abstract

The generation of reference data for deep learning models is challenging for reactive systems, and more so for combustion reactions due to the extreme conditions that create radical species and alternative spin states during the combustion process. Here, we extend intrinsic reaction coordinate (IRC) calculations with ab initio MD simulations and normal mode displacement calculations to more extensively cover the potential energy surface for 19 reaction channels for hydrogen combustion. A total of ∼290,000 potential energies and ∼1,270,000 nuclear force vectors are evaluated with a high quality range-separated hybrid density functional, ωB97X-V, to construct the reference data set, including transition state ensembles, for the deep learning models to study hydrogen combustion reaction.

Published

2022

29. Can electric fields drive chemistry for an aqueous microdroplet?

Author

Hao, Hongxia, Leven, Itai, and Head-Gordon, Teresa

Subjects

Chemical Sciences, Physical Chemistry, Bioengineering

Abstract

Reaction rates of common organic reactions have been reported to increase by one to six orders of magnitude in aqueous microdroplets compared to bulk solution, but the reasons for the rate acceleration are poorly understood. Using a coarse-grained electron model that describes structural organization and electron densities for water droplets without the expense of ab initio methods, we investigate the electric field distributions at the air-water interface to understand the origin of surface reactivity. We find that electric field alignments along free O-H bonds at the surface are ~16 MV/cm larger on average than that found for O-H bonds in the interior of the water droplet. Furthermore, electric field distributions can be an order of magnitude larger than the average due to non-linear coupling of intramolecular solvent polarization with intermolecular solvent modes which may contribute to even greater surface reactivity for weakening or breaking chemical bonds at the droplet surface.

Published

2022

30. Linear Combination of Atomic Dipoles to Calculate the Bond and Molecular Dipole Moments of Molecules and Molecular Liquids

Author

Chen, Kaixuan, Li, Wan-Lu, and Head-Gordon, Teresa

Subjects

Physical Sciences, Chemical Sciences, Physical Chemistry, Theoretical and Computational Chemistry, Chemical sciences, Physical sciences

Abstract

We report a linear combination of atomic dipole (LCAD) method for calculating the bond dipole moments of molecules. We show that the LCAD method reproduces the known molecular dipole moments of small to large molecules with a small error with respect to experimental and benchmark ab initio calculations, and molecular dipole distributions of bulk water that agree with maximally localized Wannier functions. The bond dipole moments derived from LCAD are also chemically interpretable in terms of the trend in bond ionicity in going from neutral to charged molecules. Moreover, the LCAD method accurately captures the influence of electric fields, supported by the correct trend in the change of the dipole moment under a uniform external electric field. The better grounding of bond dipole calculations indicates that it should also serve as a useful approach to bond dipole-field models used in catalysis or to reconstruct the small dipole of a H-terminated graphene flake.

Published

2021

31. Molecular magnetisabilities computed via finite fields: assessing alternatives to MP2 and revisiting magnetic exaltations in aromatic and antiaromatic species

Author

Stauch, Tim, Ganoe, Brad, Wong, Jonathan, Lee, Joonho, Rettig, Adam, Liang, Jiashu, Li, Jie, Epifanovsky, Evgeny, Head-Gordon, Teresa, and Head-Gordon, Martin

Subjects

Chemical Sciences, Physical Chemistry, Theoretical and Computational Chemistry, Molecules, magnetic properties, electron correlation, perturbation theory, optimised orbitals, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural), Chemical Physics, Physical chemistry, Theoretical and computational chemistry

Abstract

Magnetic properties of molecules such as magnetizabilities represent second order derivatives of the energy with respect to external perturbations. To avoid the need for analytic second derivatives and thereby permit evaluation of the performance of methods where they are not available, a new implementation of quantum chemistry calculations in finite applied magnetic fields is reported. This implementation is employed for a collection of small molecules with the aug-cc-pVTZ basis set to assess orbital optimized (OO) MP2 and a recently proposed regularized variant of OOMP2, called κ-OOMP2. κ-OOMP2 performs significantly better than conventional second order Møller-Plesset (MP2) theory, by reducing MP2's exaggeration of electron correlation effects. As a chemical application, we revisit an old aromaticity criterion called magnetizability exaltation. In lieu of empirical tables or increment systems to generate references, we instead use straight chain molecules with the same formal bond structure as the target cyclic planar conjugated molecules. This procedure is found to be useful for qualitative analysis, yielding exaltations that are typically negative for aromatic species and positive for antiaromatic molecules. One interesting species, N2S2, shows a positive exaltation despite having aromatic characteristics.

Published

2021

32. Critical Role of Thermal Fluctuations for CO Binding on Electrocatalytic Metal Surfaces

Author

Li, Wan-Lu, Lininger, Christianna N, Chen, Kaixuan, Welborn, Valerie Vaissier, Rossomme, Elliot, Bell, Alexis T, Head-Gordon, Martin, and Head-Gordon, Teresa

Subjects

Chemical Sciences, Physical Chemistry, thermal fluctuations, surface relaxation, CO binding, density functional theory, Chemical sciences

Abstract

This work considers the evaluation of density functional theory (DFT) when comparing against experimental observations of CO binding trends on the strong binding Pt(111) and intermediate binding Cu(111) and for weak binding Ag(111) and Au(111) surfaces important in electrocatalysis. By introducing thermal fluctuations using appropriate statistical mechanical NVT and NPT ensembles, we find that the RPBE and B97M-rV DFT functionals yield qualitatively better metal surface strain trends and CO enthalpies of binding for Cu(111) and Pt(111) than found at 0 K, thereby correcting the overbinding by 0.2 to 0.3 eV to yield better agreement with the enthalpies determined from experiment. The importance of dispersion effects are manifest for the weak CO binding Ag(111) and Au(111) surfaces at finite temperatures in which the RPBE functional does not bind CO at all, while the B97M-rV functional shows that the CO-metal interactions are a mixture of chemisorbed and physisorbed species with binding enthalpies that are within ∼0.05 eV of experiment. Across all M(111) surfaces, we show that the B97M-rV functional consistently predicts the correct atop site preference for all metals due to thermally induced surface distortions that preferentially favor the undercoordinated site. This study demonstrates the need to fully account for finite temperature fluctuations to make contact with the binding enthalpies from surface science experiments and electrocatalysis applications.

Published

2021

33. Critical Role of Thermal Fluctuations for CO Binding on Electrocatalytic Metal Surfaces.

Author

Li, Wan-Lu, Lininger, Christianna N, Chen, Kaixuan, Vaissier Welborn, Valerie, Rossomme, Elliot, Bell, Alexis T, Head-Gordon, Martin, and Head-Gordon, Teresa

Abstract

This work considers the evaluation of density functional theory (DFT) when comparing against experimental observations of CO binding trends on the strong binding Pt(111) and intermediate binding Cu(111) and for weak binding Ag(111) and Au(111) surfaces important in electrocatalysis. By introducing thermal fluctuations using appropriate statistical mechanical NVT and NPT ensembles, we find that the RPBE and B97M-rV DFT functionals yield qualitatively better metal surface strain trends and CO enthalpies of binding for Cu(111) and Pt(111) than found at 0 K, thereby correcting the overbinding by 0.2 to 0.3 eV to yield better agreement with the enthalpies determined from experiment. The importance of dispersion effects are manifest for the weak CO binding Ag(111) and Au(111) surfaces at finite temperatures in which the RPBE functional does not bind CO at all, while the B97M-rV functional shows that the CO-metal interactions are a mixture of chemisorbed and physisorbed species with binding enthalpies that are within ∼0.05 eV of experiment. Across all M(111) surfaces, we show that the B97M-rV functional consistently predicts the correct atop site preference for all metals due to thermally induced surface distortions that preferentially favor the undercoordinated site. This study demonstrates the need to fully account for finite temperature fluctuations to make contact with the binding enthalpies from surface science experiments and electrocatalysis applications.

Published

2021

34. Protein C‑GeM: A Coarse-Grained Electron Model for Fast and Accurate Protein Electrostatics Prediction

Author

Guan, Xingyi, Leven, Itai, Heidar-Zadeh, Farnaz, and Head-Gordon, Teresa

Subjects

Chemical Sciences, Physical Chemistry, Theoretical and Computational Chemistry, Networking and Information Technology R&D (NITRD), Electrons, Models, Molecular, Protein C, Quantum Theory, Static Electricity, Medicinal and Biomolecular Chemistry, Computation Theory and Mathematics, Medicinal & Biomolecular Chemistry, Medicinal and biomolecular chemistry, Theoretical and computational chemistry

Abstract

The electrostatic potential (ESP) is a powerful property for understanding and predicting electrostatic charge distributions that drive interactions between molecules. In this study, we compare various charge partitioning schemes including fitted charges, density-based quantum mechanical (QM) partitioning schemes, charge equilibration methods, and our recently introduced coarse-grained electron model, C-GeM, to describe the ESP for protein systems. When benchmarked against high quality density functional theory calculations of the ESP for tripeptides and the crambin protein, we find that the C-GeM model is of comparable accuracy to ab initio charge partitioning methods, but with orders of magnitude improvement in computational efficiency since it does not require either the electron density or the electrostatic potential as input.

Published

2021

35. Molecular Properties and Chemical Transformations Near Interfaces

Author

Ahmed, Musahid, Blum, Monika, Crumlin, Ethan J, Geissler, Phillip L, Head-Gordon, Teresa, Limmer, David T, Mandadapu, Kranthi K, Saykally, Richard J, and Wilson, Kevin R

Subjects

Physical Sciences, Chemical Sciences, Physical Chemistry, Computer Simulation, Thermodynamics, Water, CSD-04-GPCP-A, CSD-46-All CSGB, Engineering, Chemical sciences, Physical sciences

Abstract

The properties of bulk water and aqueous solutions are known to change in the vicinity of an interface and/or in a confined environment, including the thermodynamics of ion selectivity at interfaces, transition states and pathways of chemical reactions, and nucleation events and phase growth. Here we describe joint progress in identifying unifying concepts about how air, liquid, and solid interfaces can alter molecular properties and chemical reactivity compared to bulk water and multicomponent solutions. We also discuss progress made in interfacial chemistry through advancements in new theory, molecular simulation, and experiments.

Published

2021

36. Recent Advances for Improving the Accuracy, Transferability, and Efficiency of Reactive Force Fields

Author

Leven, Itai, Hao, Hongxia, Tan, Songchen, Guan, Xingyi, Penrod, Katheryn A, Akbarian, Dooman, Evangelisti, Benjamin, Hossain, Jamil, Islam, Mahbubul, Koski, Jason P, Moore, Stan, Aktulga, Hasan Metin, van Duin, Adri CT, and Head-Gordon, Teresa

Subjects

Chemical Sciences, Physical Chemistry, Theoretical and Computational Chemistry, Biochemistry and Cell Biology, Computer Software, Chemical Physics, Physical chemistry, Theoretical and computational chemistry

Abstract

Reactive force fields provide an affordable model for simulating chemical reactions at a fraction of the cost of quantum mechanical approaches. However, classically accounting for chemical reactivity often comes at the expense of accuracy and transferability, while computational cost is still large relative to nonreactive force fields. In this Perspective, we summarize recent efforts for improving the performance of reactive force fields in these three areas with a focus on the ReaxFF theoretical model. To improve accuracy, we describe recent reformulations of charge equilibration schemes to overcome unphysical long-range charge transfer, new ReaxFF models that account for explicit electrons, and corrections for energy conservation issues of the ReaxFF model. To enhance transferability we also highlight new advances to include explicit treatment of electrons in the ReaxFF and hybrid nonreactive/reactive simulations that make it possible to model charge transfer, redox chemistry, and large systems such as reverse micelles within the framework of a reactive force field. To address the computational cost, we review recent work in extended Lagrangian schemes and matrix preconditioners for accelerating the charge equilibration method component of ReaxFF and improvements in its software performance in LAMMPS.

Published

2021

37. Challenges for density functional theory: calculation of CO adsorption on electrocatalytically relevant metals

Author

Lininger, Christianna N, Gauthier, Joseph A, Li, Wan-Lu, Rossomme, Elliot, Welborn, Valerie Vaissier, Lin, Zhou, Head-Gordon, Teresa, Head-Gordon, Martin, and Bell, Alexis T

Subjects

Chemical Sciences, Physical Chemistry, Theoretical and Computational Chemistry, Chemical Physics

Abstract

Density Functional Theory (DFT) is currently the most tractable choice of theoretical model used to understand the mechanistic pathways for electrocatalytic processes such as CO2 or CO reduction. Here, we assess the performance of two DFT functionals designed specifically to describe surface interactions, RTPSS and RPBE, as well as two popular meta-GGA functionals, SCAN and B97M-rV, that have not been a priori optimized for better interfacial properties. We assess all four functionals against available experimental data for prediction of bulk and bare surface properties on four electrocatalytically relevant metals, Au, Ag, Cu, and Pt, and for binding CO to surfaces of these metals. To partially mitigate issues such as thermal and anharmonic corrections associated with comparing computations with experiments, molecular benchmarks against high level quantum chemistry are reported for CO complexes with Au, Ag, Cu and Pt atoms, as well as the CO-water complex and the water dimer. Overall, we find that the surface modified RPBE functional performs reliably for many of the benchmarks examined here, and the meta-GGA functionals also show promising results. Specifically B97M-rV predicts the correct site preference for CO binding on Ag and Au (the only functional tested here to do so), while RTPSS performs well for surface relaxations and binding of CO on Pt and Cu.

Published

2021

38. From Intermolecular Interaction Energies and Observable Shifts to Component Contributions and Back Again: A Tale of Variational Energy Decomposition Analysis

Author

Mao, Yuezhi, Loipersberger, Matthias, Horn, Paul R, Das, Akshaya, Demerdash, Omar, Levine, Daniel S, Prasad Veccham, Srimukh, Head-Gordon, Teresa, and Head-Gordon, Martin

Subjects

Inorganic Chemistry, Chemical Sciences, Physical Chemistry, Theoretical and Computational Chemistry, density functional theory, energy decomposition analysis, intermolecular interactions, hydrogen bonding, dative bonds, radical-molecule complex, force fields, radical–molecule complex, Physical Chemistry (incl. Structural), Chemical Physics, Physical chemistry, Theoretical and computational chemistry

Abstract

Quantum chemistry in the form of density functional theory (DFT) calculations is a powerful numerical experiment for predicting intermolecular interaction energies. However, no chemical insight is gained in this way beyond predictions of observables. Energy decomposition analysis (EDA) can quantitatively bridge this gap by providing values for the chemical drivers of the interactions, such as permanent electrostatics, Pauli repulsion, dispersion, and charge transfer. These energetic contributions are identified by performing DFT calculations with constraints that disable components of the interaction. This review describes the second-generation version of the absolutely localized molecular orbital EDA (ALMO-EDA-II). The effects of different physical contributions on changes in observables such as structure and vibrational frequencies upon complex formation are characterized via the adiabatic EDA. Example applications include red- versus blue-shifting hydrogen bonds; the bonding and frequency shifts of CO, N2, and BF bound to a [Ru(II)(NH3)5]2 + moiety; and the nature of the strongly bound complexes between pyridine and the benzene and naphthalene radical cations. Additionally, the use of ALMO-EDA-II to benchmark and guide the development of advanced force fields for molecular simulation is illustrated with the recent, very promising, MB-UCB potential.

Published

2021

39. Challenges for density functional theory: calculation of CO adsorption on electrocatalytically relevant metals.

Author

Lininger, Christianna N, Gauthier, Joseph A, Li, Wan-Lu, Rossomme, Elliot, Welborn, Valerie Vaissier, Lin, Zhou, Head-Gordon, Teresa, Head-Gordon, Martin, and Bell, Alexis T

Subjects

Chemical Physics, Physical Sciences, Chemical Sciences, Engineering

Abstract

Density Functional Theory (DFT) is currently the most tractable choice of theoretical model used to understand the mechanistic pathways for electrocatalytic processes such as CO2 or CO reduction. Here, we assess the performance of two DFT functionals designed specifically to describe surface interactions, RTPSS and RPBE, as well as two popular meta-GGA functionals, SCAN and B97M-rV, that have not been a priori optimized for better interfacial properties. We assess all four functionals against available experimental data for prediction of bulk and bare surface properties on four electrocatalytically relevant metals, Au, Ag, Cu, and Pt, and for binding CO to surfaces of these metals. To partially mitigate issues such as thermal and anharmonic corrections associated with comparing computations with experiments, molecular benchmarks against high level quantum chemistry are reported for CO complexes with Au, Ag, Cu and Pt atoms, as well as the CO-water complex and the water dimer. Overall, we find that the surface modified RPBE functional performs reliably for many of the benchmarks examined here, and the meta-GGA functionals also show promising results. Specifically B97M-rV predicts the correct site preference for CO binding on Ag and Au (the only functional tested here to do so), while RTPSS performs well for surface relaxations and binding of CO on Pt and Cu.

Published

2021

40. From Intermolecular Interaction Energies and Observable Shifts to Component Contributions and Back Again: A Tale of Variational Energy Decomposition Analysis.

Author

Mao, Yuezhi, Loipersberger, Matthias, Horn, Paul R, Das, Akshaya, Demerdash, Omar, Levine, Daniel S, Prasad Veccham, Srimukh, Head-Gordon, Teresa, and Head-Gordon, Martin

Subjects

dative bonds, density functional theory, energy decomposition analysis, force fields, hydrogen bonding, intermolecular interactions, radical–molecule complex, radical-molecule complex, Chemical Physics, Physical Chemistry (incl. Structural), Theoretical and Computational Chemistry

Abstract

Quantum chemistry in the form of density functional theory (DFT) calculations is a powerful numerical experiment for predicting intermolecular interaction energies. However, no chemical insight is gained in this way beyond predictions of observables. Energy decomposition analysis (EDA) can quantitatively bridge this gap by providing values for the chemical drivers of the interactions, such as permanent electrostatics, Pauli repulsion, dispersion, and charge transfer. These energetic contributions are identified by performing DFT calculations with constraints that disable components of the interaction. This review describes the second-generation version of the absolutely localized molecular orbital EDA (ALMO-EDA-II). The effects of different physical contributions on changes in observables such as structure and vibrational frequencies upon complex formation are characterized via the adiabatic EDA. Example applications include red- versus blue-shifting hydrogen bonds; the bonding and frequency shifts of CO, N2, and BF bound to a [Ru(II)(NH3)5]2 + moiety; and the nature of the strongly bound complexes between pyridine and the benzene and naphthalene radical cations. Additionally, the use of ALMO-EDA-II to benchmark and guide the development of advanced force fields for molecular simulation is illustrated with the recent, very promising, MB-UCB potential.

Published

2021

41. Configurational Entropy of Folded Proteins and Its Importance for Intrinsically Disordered Proteins.

Author

Liu, Meili, Das, Akshaya K, Lincoff, James, Sasmal, Sukanya, Cheng, Sara Y, Vernon, Robert M, Forman-Kay, Julie D, and Head-Gordon, Teresa

Subjects

configurational entropy, force fields, intrinsically disordered proteins, Other Chemical Sciences, Genetics, Other Biological Sciences, Chemical Physics

Abstract

Many pairwise additive force fields are in active use for intrinsically disordered proteins (IDPs) and regions (IDRs), some of which modify energetic terms to improve the description of IDPs/IDRs but are largely in disagreement with solution experiments for the disordered states. This work considers a new direction-the connection to configurational entropy-and how it might change the nature of our understanding of protein force field development to equally well encompass globular proteins, IDRs/IDPs, and disorder-to-order transitions. We have evaluated representative pairwise and many-body protein and water force fields against experimental data on representative IDPs and IDRs, a peptide that undergoes a disorder-to-order transition, for seven globular proteins ranging in size from 130 to 266 amino acids. We find that force fields with the largest statistical fluctuations consistent with the radius of gyration and universal Lindemann values for folded states simultaneously better describe IDPs and IDRs and disorder-to-order transitions. Hence, the crux of what a force field should exhibit to well describe IDRs/IDPs is not just the balance between protein and water energetics but the balance between energetic effects and configurational entropy of folded states of globular proteins.

Published

2021

42. AutoDetect-mNP: An Unsupervised Machine Learning Algorithm for Automated Analysis of Transmission Electron Microscope Images of Metal Nanoparticles

Author

Wang, Xingzhi, Li, Jie, Ha, Hyun Dong, Dahl, Jakob C, Ondry, Justin C, Moreno-Hernandez, Ivan, Head-Gordon, Teresa, and Alivisatos, A Paul

Subjects

Bioengineering, Nanotechnology, transmission electron microscopy, nanoparticles, machine learning, unsupervised learning, image analysis

Abstract

The synthesis quality of artificial inorganic nanocrystals is most often assessed by transmission electron microscopy (TEM) for which high-throughput advances have dramatically increased both the quantity and information richness of metal nanoparticle (mNP) characterization. Existing automated data analysis algorithms of TEM mNP images generally adopt a supervised approach, requiring a significant effort in human preparation of labeled data that reduces objectivity, efficiency, and generalizability. We have developed an unsupervised algorithm AutoDetect-mNP for automated analysis of TEM images that objectively extracts morphological information on convex mNPs from TEM images based on their shape attributes, requiring little to no human input in the process. The performance of AutoDetect-mNP is tested on two data sets of bright field TEM images of Au nanoparticles with different shapes and further extended to palladium nanocubes and cadmium selenide quantum dots, demonstrating that the algorithm is quantitatively reliable and can thus serve as a generalizable measure of the morphology distributions of any mNP synthesis. The AutoDetect-mNP algorithm will aid in future developments of high-throughput characterization of mNPs and the future advent of time-resolved TEM studies that can investigate reaction mechanisms of mNP synthesis and reactivity.

Published

2021

43. AutoDetect-mNP: An Unsupervised Machine Learning Algorithm for Automated Analysis of Transmission Electron Microscope Images of Metal Nanoparticles.

Author

Wang, Xingzhi, Li, Jie, Ha, Hyun Dong, Dahl, Jakob C, Ondry, Justin C, Moreno-Hernandez, Ivan, Head-Gordon, Teresa, and Alivisatos, A Paul

Abstract

The synthesis quality of artificial inorganic nanocrystals is most often assessed by transmission electron microscopy (TEM) for which high-throughput advances have dramatically increased both the quantity and information richness of metal nanoparticle (mNP) characterization. Existing automated data analysis algorithms of TEM mNP images generally adopt a supervised approach, requiring a significant effort in human preparation of labeled data that reduces objectivity, efficiency, and generalizability. We have developed an unsupervised algorithm AutoDetect-mNP for automated analysis of TEM images that objectively extracts morphological information on convex mNPs from TEM images based on their shape attributes, requiring little to no human input in the process. The performance of AutoDetect-mNP is tested on two data sets of bright field TEM images of Au nanoparticles with different shapes and further extended to palladium nanocubes and cadmium selenide quantum dots, demonstrating that the algorithm is quantitatively reliable and can thus serve as a generalizable measure of the morphology distributions of any mNP synthesis. The AutoDetect-mNP algorithm will aid in future developments of high-throughput characterization of mNPs and the future advent of time-resolved TEM studies that can investigate reaction mechanisms of mNP synthesis and reactivity.

Published

2021

44. Catalytic Principles from Natural Enzymes and Translational Design Strategies for Synthetic Catalysts

Author

Li, Wan-Lu and Head-Gordon, Teresa

Subjects

Macromolecular and Materials Chemistry, Chemical Sciences, Chemical sciences

Abstract

As biocatalysts, enzymes are characterized by their high catalytic efficiency and strong specificity but are relatively fragile by requiring narrow and specific reactive conditions for activity. Synthetic catalysts offer an opportunity for more chemical versatility operating over a wider range of conditions but currently do not reach the remarkable performance of natural enzymes. Here we consider some new design strategies based on the contributions of nonlocal electric fields and thermodynamic fluctuations to both improve the catalytic step and turnover for rate acceleration in arbitrary synthetic catalysts through bioinspired studies of natural enzymes. With a focus on the enzyme as a whole catalytic construct, we illustrate the translational impact of natural enzyme principles to synthetic enzymes, supramolecular capsules, and electrocatalytic surfaces.

Published

2021

45. PED in 2021: a major update of the protein ensemble database for intrinsically disordered proteins

Author

Lazar, Tamas, Martínez-Pérez, Elizabeth, Quaglia, Federica, Hatos, András, Chemes, Lucía B, Iserte, Javier A, Méndez, Nicolás A, Garrone, Nicolás A, Saldaño, Tadeo E, Marchetti, Julia, Rueda, Ana Julia Velez, Bernadó, Pau, Blackledge, Martin, Cordeiro, Tiago N, Fagerberg, Eric, Forman-Kay, Julie D, Fornasari, Maria S, Gibson, Toby J, Gomes, Gregory-Neal W, Gradinaru, Claudiu C, Head-Gordon, Teresa, Jensen, Malene Ringkjøbing, Lemke, Edward A, Longhi, Sonia, Marino-Buslje, Cristina, Minervini, Giovanni, Mittag, Tanja, Monzon, Alexander Miguel, Pappu, Rohit V, Parisi, Gustavo, Ricard-Blum, Sylvie, Ruff, Kiersten M, Salladini, Edoardo, Skepö, Marie, Svergun, Dmitri, Vallet, Sylvain D, Varadi, Mihaly, Tompa, Peter, Tosatto, Silvio CE, and Piovesan, Damiano

Subjects

Biological Sciences, Bioinformatics and Computational Biology, Generic health relevance, Databases, Protein, Humans, Intrinsically Disordered Proteins, Search Engine, Tumor Suppressor Protein p53, Environmental Sciences, Information and Computing Sciences, Developmental Biology, Biological sciences, Chemical sciences, Environmental sciences

Abstract

The Protein Ensemble Database (PED) (https://proteinensemble.org), which holds structural ensembles of intrinsically disordered proteins (IDPs), has been significantly updated and upgraded since its last release in 2016. The new version, PED 4.0, has been completely redesigned and reimplemented with cutting-edge technology and now holds about six times more data (162 versus 24 entries and 242 versus 60 structural ensembles) and a broader representation of state of the art ensemble generation methods than the previous version. The database has a completely renewed graphical interface with an interactive feature viewer for region-based annotations, and provides a series of descriptors of the qualitative and quantitative properties of the ensembles. High quality of the data is guaranteed by a new submission process, which combines both automatic and manual evaluation steps. A team of biocurators integrate structured metadata describing the ensemble generation methodology, experimental constraints and conditions. A new search engine allows the user to build advanced queries and search all entry fields including cross-references to IDP-related resources such as DisProt, MobiDB, BMRB and SASBDB. We expect that the renewed PED will be useful for researchers interested in the atomic-level understanding of IDP function, and promote the rational, structure-based design of IDP-targeting drugs.

Published

2021

46. Configurational Entropy of Folded Proteins and Its Importance for Intrinsically Disordered Proteins

Author

Liu, Meili, Das, Akshaya K, Lincoff, James, Sasmal, Sukanya, Cheng, Sara Y, Vernon, Robert M, Forman-Kay, Julie D, and Head-Gordon, Teresa

Subjects

Bayes Theorem, Computer Simulation, Entropy, Intrinsically Disordered Proteins, Magnetic Resonance Spectroscopy, Molecular Dynamics Simulation, Peptides, Polymers, Protein Conformation, Protein Engineering, Protein Folding, Protein Structure, Secondary, Solvents, Static Electricity, Temperature, configurational entropy, force fields, intrinsically disordered proteins, Other Chemical Sciences, Genetics, Other Biological Sciences, Chemical Physics

Abstract

Many pairwise additive force fields are in active use for intrinsically disordered proteins (IDPs) and regions (IDRs), some of which modify energetic terms to improve the description of IDPs/IDRs but are largely in disagreement with solution experiments for the disordered states. This work considers a new direction-the connection to configurational entropy-and how it might change the nature of our understanding of protein force field development to equally well encompass globular proteins, IDRs/IDPs, and disorder-to-order transitions. We have evaluated representative pairwise and many-body protein and water force fields against experimental data on representative IDPs and IDRs, a peptide that undergoes a disorder-to-order transition, for seven globular proteins ranging in size from 130 to 266 amino acids. We find that force fields with the largest statistical fluctuations consistent with the radius of gyration and universal Lindemann values for folded states simultaneously better describe IDPs and IDRs and disorder-to-order transitions. Hence, the crux of what a force field should exhibit to well describe IDRs/IDPs is not just the balance between protein and water energetics but the balance between energetic effects and configurational entropy of folded states of globular proteins.

Published

2021

47. Proton Traffic Jam: Effect of Nanoconfinement and Acid Concentration on Proton Hopping Mechanism

Author

Adams, Ellen M, Hao, Hongxia, Leven, Itai, Ruettermann, Maximilian, Wirtz, Hanna, Havenith, Martina, and Head-Gordon, Teresa

Subjects

confined water, Grotthuss mechanism, micelles, proton hopping, THz spectroscopy, CSD-03-CPIMS-A, CSD-46-All CSGB, Chemical Sciences, Organic Chemistry, Chemical sciences

Abstract

The properties of the water network in concentrated HCl acid pools in nanometer-sized reverse nonionic micelles were probed with TeraHertz absorption, dielectric relaxation spectroscopy, and reactive force field simulations capable of describing proton hopping mechanisms. We identify that only at a critical micelle size of W0 =9 do solvated proton complexes form in the water pool, accompanied by a change in mechanism from Grotthuss forward shuttling to one that favors local oscillatory hopping. This is due to a preference for H+ and Cl- ions to adsorb to the micelle interface, together with an acid concentration effect that causes a "traffic jam" in which the short-circuiting of the hydrogen-bonding motif of the hydronium ion decreases the forward hopping rate throughout the water interior even as the micelle size increases. These findings have implications for atmospheric chemistry, biochemical and biophysical environments, and energy materials, as transport of protons vital to these processes can be suppressed due to confinement, aggregation, and/or concentration.

Published

2021

48. PED in 2021: a major update of the protein ensemble database for intrinsically disordered proteins.

Author

Lazar, Tamas, Martínez-Pérez, Elizabeth, Quaglia, Federica, Hatos, András, Chemes, Lucía B, Iserte, Javier A, Méndez, Nicolás A, Garrone, Nicolás A, Saldaño, Tadeo E, Marchetti, Julia, Rueda, Ana Julia Velez, Bernadó, Pau, Blackledge, Martin, Cordeiro, Tiago N, Fagerberg, Eric, Forman-Kay, Julie D, Fornasari, Maria S, Gibson, Toby J, Gomes, Gregory-Neal W, Gradinaru, Claudiu C, Head-Gordon, Teresa, Jensen, Malene Ringkjøbing, Lemke, Edward A, Longhi, Sonia, Marino-Buslje, Cristina, Minervini, Giovanni, Mittag, Tanja, Monzon, Alexander Miguel, Pappu, Rohit V, Parisi, Gustavo, Ricard-Blum, Sylvie, Ruff, Kiersten M, Salladini, Edoardo, Skepö, Marie, Svergun, Dmitri, Vallet, Sylvain D, Varadi, Mihaly, Tompa, Peter, Tosatto, Silvio CE, and Piovesan, Damiano

Subjects

Developmental Biology, Environmental Sciences, Biological Sciences, Information and Computing Sciences

Abstract

The Protein Ensemble Database (PED) (https://proteinensemble.org), which holds structural ensembles of intrinsically disordered proteins (IDPs), has been significantly updated and upgraded since its last release in 2016. The new version, PED 4.0, has been completely redesigned and reimplemented with cutting-edge technology and now holds about six times more data (162 versus 24 entries and 242 versus 60 structural ensembles) and a broader representation of state of the art ensemble generation methods than the previous version. The database has a completely renewed graphical interface with an interactive feature viewer for region-based annotations, and provides a series of descriptors of the qualitative and quantitative properties of the ensembles. High quality of the data is guaranteed by a new submission process, which combines both automatic and manual evaluation steps. A team of biocurators integrate structured metadata describing the ensemble generation methodology, experimental constraints and conditions. A new search engine allows the user to build advanced queries and search all entry fields including cross-references to IDP-related resources such as DisProt, MobiDB, BMRB and SASBDB. We expect that the renewed PED will be useful for researchers interested in the atomic-level understanding of IDP function, and promote the rational, structure-based design of IDP-targeting drugs.

Published

2021

49. Catalytic Principles from Natural Enzymes and Translational Design Strategies for Synthetic Catalysts.

Author

Li, Wan-Lu and Head-Gordon, Teresa

Subjects

Chemical Sciences

Abstract

As biocatalysts, enzymes are characterized by their high catalytic efficiency and strong specificity but are relatively fragile by requiring narrow and specific reactive conditions for activity. Synthetic catalysts offer an opportunity for more chemical versatility operating over a wider range of conditions but currently do not reach the remarkable performance of natural enzymes. Here we consider some new design strategies based on the contributions of nonlocal electric fields and thermodynamic fluctuations to both improve the catalytic step and turnover for rate acceleration in arbitrary synthetic catalysts through bioinspired studies of natural enzymes. With a focus on the enzyme as a whole catalytic construct, we illustrate the translational impact of natural enzyme principles to synthetic enzymes, supramolecular capsules, and electrocatalytic surfaces.

Published

2021

50. An isolated water droplet in the aqueous solution of a supramolecular tetrahedral cage

Author

Sebastiani, Federico, Bender, Trandon A, Pezzotti, Simone, Li, Wan-Lu, Schwaab, Gerhard, Bergman, Robert G, Raymond, Kenneth N, Toste, F Dean, Head-Gordon, Teresa, and Havenith, Martina

Subjects

Macromolecular and Materials Chemistry, Chemical Sciences, Physical Sciences, Gallium, Hydrophobic and Hydrophilic Interactions, Ligands, Molecular Dynamics Simulation, Water, supramolecular, encapsulation, THz spectroscopy, ab initio molecular dynamics, confined water

Abstract

Water under nanoconfinement at ambient conditions has exhibited low-dimensional ice formation and liquid-solid phase transitions, but with structural and dynamical signatures that map onto known regions of water's phase diagram. Using terahertz (THz) absorption spectroscopy and ab initio molecular dynamics, we have investigated the ambient water confined in a supramolecular tetrahedral assembly, and determined that a dynamically distinct network of 9 ± 1 water molecules is present within the nanocavity of the host. The low-frequency absorption spectrum and theoretical analysis of the water in the Ga4L612- host demonstrate that the structure and dynamics of the encapsulated droplet is distinct from any known phase of water. A further inference is that the release of the highly unusual encapsulated water droplet creates a strong thermodynamic driver for the high-affinity binding of guests in aqueous solution for the Ga4L612- supramolecular construct.

Published

2020