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1. Workhorse minimally-empirical dispersion-corrected density functional, with tests for weakly-bound systems: r$^{2}$SCAN+rVV10

Author

Ning, Jinliang, Kothakonda, Manish, Furness, James W., Kaplan, Aaron D., Ehlert, Sebastian, Brandenburg, Jan Gerit, Perdew, John P., and Sun, Jianwei

Subjects
Condensed Matter - Materials Science, Condensed Matter - Soft Condensed Matter, Physics - Atomic and Molecular Clusters, Physics - Computational Physics
Abstract

SCAN+rVV10 has been demonstrated to be a versatile van der Waals (vdW) density functional that delivers good predictions of both energetic and structural properties for many types of bonding. Recently, the r$^{2}$SCAN functional has been devised as a revised form of SCAN with improved numerical stability. In this work, we refit the rVV10 functional to optimize the r$^{2}$SCAN+rVV10 vdW density functional, and test its performance for molecular interactions and layered materials. Our molecular tests demonstrate that r$^{2}$SCAN+rVV10 outperforms its predecessor SCAN+rVV10 in both efficiency (numerical stability) and accuracy. This good performance is also found in lattice constant predictions. In comparison with benchmark results from higher-level theories or experiments, r$^{2}$SCAN+rVV10 yields excellent interlayer binding energies and phonon dispersions for layered materials.

Published
2022
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2. r2SCAN-D4: Dispersion corrected meta-generalized gradient approximation for general chemical applications

Author

Ehlert, Sebastian, Huniar, Uwe, Ning, Jinliang, Furness, James W., Sun, Jianwei, Kaplan, Aaron D., Perdew, John P., and Brandenburg, Jan Gerit

Subjects
Physics - Chemical Physics
Abstract

We combine a regularized variant of the strongly constrained and appropriately normed semilocal density functional [J. Sun, A. Ruzsinszky, and J. P. Perdew, Phys. Rev. Lett. 115, 036402 (2015)] with the latest generation semi-classical London dispersion correction. The resulting density functional approximation r2SCAN-D4 has the speed of generalized gradient approximations while approaching the accuracy of hybrid functionals for general chemical applications. We demonstrate its numerical robustness in real-life settings and benchmark molecular geometries, general main group and organo-metallic thermochemistry, as well as non-covalent interactions in supramolecular complexes and molecular crystals. Main group and transition metal bond lengths have errors of just 0.8%, which is competitive with hybrid functionals for main group molecules and outperforms them for transition metal complexes. The weighted mean absolute deviation (WTMAD2) on the large GMTKN55 database of chemical properties is exceptionally small at 7.5 kcal/mol. This also holds for metal organic reactions with an MAD of 3.3 kcal/mol. The versatile applicability to organic and metal-organic systems transfers to condensed systems, where lattice energies of molecular crystals are within chemical accuracy (errors <1 kcal/mol).

Published
2020
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3. Interactions between Large Molecules: Puzzle for Reference Quantum-Mechanical Methods

Author

Al-Hamdani, Yasmine S., Nagy, Péter R., Barton, Dennis, Kállay, Mihály, Brandenburg, Jan Gerit, and Tkatchenko, Alexandre

Subjects
Physics - Chemical Physics, Physics - Atomic and Molecular Clusters
Abstract

Quantum-mechanical methods are widely used for understanding molecular interactions throughout biology, chemistry, and materials science. Quantum diffusion Monte Carlo (DMC) and coupled cluster with single, double, and perturbative triple excitations [CCSD(T)] are two state-of-the-art and trusted wavefunction methods that have been categorically shown to yield accurate interaction energies for small organic molecules. These methods provide valuable reference information for widely-used semi-empirical and machine learning potentials, especially where experimental information is scarce. However, agreement for systems beyond small molecules is a crucial remaining milestone for cementing the benchmark accuracy of these methods. Approaching such well-converged predictive power in larger molecules has motivated major developments in CCSD(T) as well as DMC algorithms in the past years, resulting in orders of magnitude time-to-solution reductions. Here, we show that CCSD(T) and DMC interaction energies are not in consistent agreement for a set of polarizable supramolecules. Whilst agreement is found for some of the complexes, in a few key systems disagreements of up to 8 kcal/mol remained. This leads to differences of up to 6 orders of magnitude in the corresponding binding association constant at room temperature for systems which are well within the accustomed domain of applicability for both methods. These findings thus indicate that more caution is required when aiming at reproducible non-covalent interactions between extended molecules. Our data contradicts the expectation that the most comprehensive and robust wavefunction methods predict identical non-covalent interactions and indicate an unsolved challenge for benchmark approaches.

Published
2020
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4. Free-energy landscape of polymer-crystal polymorphism

Author

Liu, Chan, Brandenburg, Jan Gerit, Valsson, Omar, Kremer, Kurt, and Bereau, Tristan

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

Polymorphism rationalizes how processing can control the final structure of a material. The rugged free-energy landscape and exceedingly slow kinetics in the solid state have so far hampered computational investigations. We report for the first time the free-energy landscape of a polymorphic crystalline polymer, syndiotactic polystyrene. Coarse-grained metadynamics simulations allow us to efficiently sample the landscape at large. The free-energy difference between the two main polymorphs, $\alpha$ and $\beta$, is further investigated by quantum-chemical calculations. The two methods are in line with experimental observations: they predict $\beta$ as the more stable polymorph at standard conditions. Critically, the free-energy landscape suggests how the $\alpha$ polymorph may lead to experimentally observed kinetic traps. The combination of multiscale modeling, enhanced sampling, and quantum-chemical calculations offers an appealing strategy to uncover complex free-energy landscapes with polymorphic behavior., Comment: 10 pages, 4 figures

Published
2020

5. Extracting ice phases from liquid water: why a machine-learning water model generalizes so well

Author

Monserrat, Bartomeu, Brandenburg, Jan Gerit, Engel, Edgar A., and Cheng, Bingqing

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

We investigate the structural similarities between liquid water and 53 ices, including 20 knowncrystalline phases. We base such similarity comparison on the local environments that consist of atoms within a certain cutoff radius of a central atom. We reveal that liquid water explores the localenvironments of the diverse ice phases, by directly comparing the environments in these phases using general atomic descriptors, and also by demonstrating that a machine-learning potential trained on liquid water alone can predict the densities, the lattice energies, and vibrational properties of theices. The finding that the local environments characterising the different ice phases are found in water sheds light on water phase behaviors, and rationalizes the transferability of water models between different phases.

Published
2020

6. Interaction between water and carbon nanostructures: How good are current density functional approximations?

Author

Brandenburg, Jan Gerit, Zen, Andrea, Alfè, Dario, and Michaelides, Angelos

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

Due to their current and future technological applications, including realisation of water filters and desalination membranes, water adsorption on graphitic sp$^{2}$-bonded carbon is of overwhelming interest. However, these systems are notoriously challenging to model, even for electronic structure methods such as density functional theory (DFT), because of the crucial role played by London dispersion forces and non-covalent interactions in general. Recent efforts have established reference quality interactions of several carbon nanostructures interacting with water. Here, we compile a new benchmark set (dubbed \textbf{WaC18}), which includes a single water molecule interacting with a broad range of carbon structures, and various bulk (3D) and two dimensional (2D) ice polymorphs. The performance of 28 approaches, including semi-local exchange-correlation functionals, non-local (Fock) exchange contributions, and long-range van der Waals (vdW) treatments, are tested by computing the deviations from the reference interaction energies. The calculated mean absolute deviations on the WaC18 set depends crucially on the DFT approach, ranging from 135 meV for LDA to 12 meV for PBE0-D4. We find that modern vdW corrections to DFT significantly improve over their precursors. Within the 28 tested approaches, we identify the best performing within the functional classes of: generalized gradient approximated (GGA), meta-GGA, vdW-DF, and hybrid DF, which are BLYP-D4, TPSS-D4, rev-vdW-DF2, and PBE0-D4, respectively.

Published
2019
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7. A new scheme for fixed node diffusion quantum Monte Carlo with pseudopotentials: improving reproducibility and reducing the trial-wave-function bias

Author

Zen, Andrea, Brandenburg, Jan Gerit, Michaelides, Angelos, and Alfè, Dario

Subjects
Physics - Computational Physics, Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons, Physics - Chemical Physics, Quantum Physics
Abstract

Fixed node diffusion quantum Monte Carlo (FN-DMC) is an increasingly used computational approach for investigating the electronic structure of molecules, solids, and surfaces with controllable accuracy. It stands out among equally accurate electronic structure approaches for its favorable cubic scaling with system size, which often makes FN-DMC the only computationally affordable high-quality method in large condensed phase systems with more than 100 atoms. In such systems FN-DMC deploys pseudopotentials to substantially improve efficiency. In order to deal with non-local terms of pseudopotentials, the FN-DMC algorithm must use an additional approximation, leading to the so-called localization error. However, the two available approximations, the locality approximation (LA) and the T-move approximation (TM), have certain disadvantages and can make DMC calculations difficult to reproduce. Here we introduce a third approach, called the determinant localization approximation (DLA). DLA eliminates reproducibility issues and systematically provides good quality results and stable simulations that are slightly more efficient than LA and TM. When calculating energy differences -- such as interaction and ionization energies -- DLA is also more accurate than the LA and TM approaches. We believe that DLA paves the way to the automization of FN-DMC and its much easier application in large systems.

Published
2019
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8. On the physisorption of water on graphene: Sub-chemical accuracy from many-body electronic structure methods

Author

Brandenburg, Jan Gerit, Zen, Andrea, Fitzner, Martin, Ramberger, Benjamin, Kresse, Georg, Tsatsoulis, Theodoros, Grüneis, Andreas, Michaelides, Angelos, and Alfè, Dario

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

Molecular adsorption on surfaces plays a central role in catalysis, corrosion, desalination, and many other processes of relevance to industry and the natural world. Few adsorption systems are more ubiquitous or of more widespread importance than those involving water and carbon, and for a molecular level understanding of such interfaces water monomer adsorption on graphene is a fundamental and representative system. This system is particularly interesting as it calls for an accurate treatment of electron correlation effects, as well as posing a practical challenge to experiments. Here, we employ many-body electronic structure methodologies that can be rigorously converged and thus provide faithful references for the molecule-surface interaction. In particular, we use diffusion Monte-Carlo (DMC), coupled cluster (CCSD(T)), as well as the random phase approximation (RPA) to calculate the strength of the interaction between water and an extended graphene surface. We establish excellent, sub-chemical, agreement between the complementary high-level methodologies, and an adsorption energy estimate in the most stable configuration of approximately -100\,meV is obtained. We also find that the adsorption energy is rather insensitive to the orientation of the water molecule on the surface, despite different binding motifs involving qualitatively different interfacial charge reorganisation. In producing the first demonstrably accurate adsorption energies for water on graphene this work also resolves discrepancies amongst previously reported values for this widely studied system. It also paves the way for more accurate and reliable studies of liquid water at carbon interfaces with cheaper computational methods, such as density functional theory and classical potentials.

Published
2018
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9. Fast and accurate quantum Monte Carlo for molecular crystals

Author

Zen, Andrea, Brandenburg, Jan Gerit, Klimeš, Jiří, Tkatchenko, Alexandre, Alfè, Dario, and Michaelides, Angelos

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

Computer simulation plays a central role in modern day materials science. The utility of a given computational approach depends largely on the balance it provides between accuracy and computational cost. Molecular crystals are a class of materials of great technological importance which are challenging for even the most sophisticated \emph{ab initio} electronic structure theories to accurately describe. This is partly because they are held together by a balance of weak intermolecular forces but also because the primitive cells of molecular crystals are often substantially larger than those of atomic solids. Here, we demonstrate that diffusion quantum Monte Carlo (DMC) delivers sub-chemical accuracy for a diverse set of molecular crystals at a surprisingly moderate computational cost. As such, we anticipate that DMC can play an important role in understanding and predicting the properties of a large number of molecular crystals, including those built from relatively large molecules which are far beyond reach of other high accuracy methods.

Published
2018
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10. Evidence for Stable Square Ice from Quantum Monte Carlo

Author

Chen, Ji, Zen, Andrea, Brandenburg, Jan Gerit, Alfè, Dario, and Michaelides, Angelos

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

Recent experiments on ice formed by water under nanoconfinement provide evidence for a two-dimensional (2D) `square ice' phase. However, the interpretation of the experiments has been questioned and the stability of square ice has become a matter of debate. Partially this is because the simulation approaches employed so far (force fields and density functional theory) struggle to accurately describe the very small energy differences between the relevant phases. Here we report a study of 2D ice using an accurate wave-function based electronic structure approach, namely Diffusion Monte Carlo (DMC). We find that at relatively high pressure square ice is indeed the lowest enthalpy phase examined, supporting the initial experimental claim. Moreover, at lower pressures a `pentagonal ice' phase (not yet observed experimentally) has the lowest enthalpy, and at ambient pressure the `pentagonal ice' phase is degenerate with a `hexagonal ice' phase. Our DMC results also allow us to evaluate the accuracy of various density functional theory exchange correlation functionals and force field models, and in doing so we extend the understanding of how such methodologies perform to challenging 2D structures presenting dangling hydrogen bonds.

Published
2016
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11. NanoSolveIT Project: Driving nanoinformatics research to develop innovative and integrated tools for in silico nanosafety assessment

Author

Afantitis, Antreas, Melagraki, Georgia, Isigonis, Panagiotis, Tsoumanis, Andreas, Varsou, Dimitra Danai, Valsami-Jones, Eugenia, Papadiamantis, Anastasios, Ellis, Laura-Jayne A., Sarimveis, Haralambos, Doganis, Philip, Karatzas, Pantelis, Tsiros, Periklis, Liampa, Irene, Lobaskin, Vladimir, Greco, Dario, Serra, Angela, Kinaret, Pia Anneli Sofia, Saarimäki, Laura Aliisa, Grafström, Roland, Kohonen, Pekka, Nymark, Penny, Willighagen, Egon, Puzyn, Tomasz, Rybinska-Fryca, Anna, Lyubartsev, Alexander, Alstrup Jensen, Keld, Brandenburg, Jan Gerit, Lofts, Stephen, Svendsen, Claus, Harrison, Samuel, Maier, Dieter, Tamm, Kaido, Jänes, Jaak, Sikk, Lauri, Dusinska, Maria, Longhin, Eleonora, Rundén-Pran, Elise, Mariussen, Espen, El Yamani, Naouale, Unger, Wolfgang, Radnik, Jörg, Tropsha, Alexander, Cohen, Yoram, Leszczynski, Jerzy, Ogilvie Hendren, Christine, Wiesner, Mark, Winkler, David, Suzuki, Noriyuki, Yoon, Tae Hyun, Choi, Jang-Sik, Sanabria, Natasha, Gulumian, Mary, and Lynch, Iseult

Published
2020
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15. Metal–organic frameworks properties from hybrid density functional approximations.

Author

Donà, Lorenzo, Brandenburg, Jan Gerit, and Civalleri, Bartolomeo

Subjects
*METAL-organic frameworks, *DISPERSIVE interactions, *UNIT cell, *DENSITY functional theory, *ELECTRONIC structure
Abstract

The chemical versatility and modular nature of Metal–Organic Frameworks (MOFs) make them unique hybrid inorganic–organic materials for several important applications. From a computational point of view, ab initio modeling of MOFs is a challenging and demanding task, in particular, when the system reaches the size of gigantic MOFs as MIL-100 and MIL-101 (where MIL stands for Materials Institute Lavoisier) with several thousand atoms in the unit cell. Here, we show how such complex systems can be successfully tackled by a recently proposed class of composite electronic structure methods revised for solid-state calculations. These methods rely on HF/density functional theory hybrid functionals (i.e., PBEsol0 and HSEsol) combined with a double-zeta quality basis set. They are augmented with semi-classical corrections to take into account dispersive interactions (D3 scheme) and the basis set superposition error (gCP). The resulting methodologies, dubbed "sol-3c," are cost-effective yet reach the hybrid functional accuracy. Here, sol-3c methods are effectively applied to predict the structural, vibrational, electronic, and adsorption properties of some of the most common MOFs. Calculations are feasible even on very large MOFs containing more than 2500 atoms in the unit cell as MIL-100 and MIL-101 with reasonable computing resources. We propose to use our composite methods for the routine in silico screening of MOFs targeting properties beyond plain structural features. [ABSTRACT FROM AUTHOR]

Published
2022
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16. Effect of Polymer Additives on the Crystal Habit of Metformin HCl

Author

Bellucci, Michael A., primary, Marx, Anke, additional, Wang, Bing, additional, Fang, Liwen, additional, Zhou, Yunfei, additional, Greenwell, Chandler, additional, Li, Zhuhong, additional, Becker, Axel, additional, Sun, GuangXu, additional, Brandenburg, Jan Gerit, additional, and Sekharan, Sivakumar, additional

Published
2023
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18. Dispersion Corrected Hartree–Fock and Density Functional Theory for Organic Crystal Structure Prediction

Author

Brandenburg, Jan Gerit, Grimme, Stefan, Houk, K.N., Series editor, Hunter, C.A., Series editor, Krische, Michael J, Series editor, Lehn, J.-M., Series editor, Ley, S.V., Series editor, Olivucci, M., Series editor, Thiem, J., Series editor, Venturi, M., Series editor, Wong, Chi-Huey, Series editor, Wong, Henry N.C., Series editor, Atahan-Evrenk, Sule, editor, and Aspuru-Guzik, Alan, editor

Published
2014
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19. r2SCAN-D4: Dispersion corrected meta-generalized gradient approximation for general chemical applications.

Author

Ehlert, Sebastian, Huniar, Uwe, Ning, Jinliang, Furness, James W., Sun, Jianwei, Kaplan, Aaron D., Perdew, John P., and Brandenburg, Jan Gerit

Subjects
MOLECULAR crystals, MOLECULAR shapes, THERMOCHEMISTRY, TRANSITION metal complexes, METAL bonding, DISPERSION (Chemistry)
Abstract

We combine a regularized variant of the strongly constrained and appropriately normed semilocal density functional [J. Sun, A. Ruzsinszky, and J. P. Perdew, Phys. Rev. Lett. 115, 036402 (2015)] with the latest generation semi-classical London dispersion correction. The resulting density functional approximation r2SCAN-D4 has the speed of generalized gradient approximations while approaching the accuracy of hybrid functionals for general chemical applications. We demonstrate its numerical robustness in real-life settings and benchmark molecular geometries, general main group and organo-metallic thermochemistry, and non-covalent interactions in supramolecular complexes and molecular crystals. Main group and transition metal bond lengths have errors of just 0.8%, which is competitive with hybrid functionals for main group molecules and outperforms them for transition metal complexes. The weighted mean absolute deviation (WTMAD2) on the large GMTKN55 database of chemical properties is exceptionally small at 7.5 kcal/mol. This also holds for metal organic reactions with an MAD of 3.3 kcal/mol. The versatile applicability to organic and metal–organic systems transfers to condensed systems, where lattice energies of molecular crystals are within the chemical accuracy (errors <1 kcal/mol). [ABSTRACT FROM AUTHOR]

Published
2021
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21. Contributors

Author

Beran, Gregory J.O., primary, Berland, Kristian, additional, Brandenburg, Jan Gerit, additional, Brédas, Jean-Luc, additional, Cooper, Valentino R., additional, DiLabio, Gino A., additional, Ford, Michael J., additional, Francisco, E., additional, Goerigk, Lars, additional, Gould, Tim, additional, Hartman, Joshua D., additional, Heit, Yonaton N., additional, Heßelmann, Andreas, additional, Hyldgaard, Per, additional, Johnson, Erin R., additional, Lam, Christopher N., additional, Li, Musen, additional, Lundqvist, Bengt I., additional, Martín Pendás, A., additional, Mennucci, Benedetta, additional, Price, Sarah L., additional, Ravva, Mahesh Kumar, additional, Reimers, Jeffrey R., additional, Risko, Chad, additional, Schröder, Elsebeth, additional, Sherrill, C. David, additional, Stone, Anthony J., additional, Sumpter, Bobby G., additional, Thonhauser, Timo, additional, Wan, Dongya, additional, and Wang, Yangyang, additional

Published
2017
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24. Properties of the water to boron nitride interaction: From zero to two dimensions with benchmark accuracy.

Author

Al-Hamdani, Yasmine S., Rossi, Mariana, Alfè, Dario, Tsatsoulis, Theodoros, Ramberger, Benjamin, Brandenburg, Jan Gerit, Zen, Andrea, Kresse, Georg, Grüneis, Andreas, Tkatchenko, Alexandre, and Michaelides, Angelos

Subjects
BORON nitride, SURFACE chemistry, CATALYSIS, ADSORPTION (Chemistry), ELECTRONIC structure, ELECTROSTATICS
Abstract

Molecular adsorption on surfaces plays an important part in catalysis, corrosion, desalination, and various other processes that are relevant to industry and in nature. As a complement to experiments, accurate adsorption energies can be obtained using various sophisticated electronic structure methods that can now be applied to periodic systems. The adsorption energy of water on boron nitride substrates, going from zero to 2-dimensional periodicity, is particularly interesting as it calls for an accurate treatment of polarizable electrostatics and dispersion interactions, as well as posing a practical challenge to experiments and electronic structure methods. Here, we present reference adsorption energies, static polarizabilities, and dynamic polarizabilities, for water on BN substrates of varying size and dimension. Adsorption energies are computed with coupled cluster theory, fixed-node quantum Monte Carlo (FNQMC), the random phase approximation, and second order Møller-Plesset theory. These wavefunction based correlated methods are found to agree in molecular as well as periodic systems. The best estimate of the water/h-BN adsorption energy is -107±7 meV from FNQMC. In addition, the water adsorption energy on the BN substrates could be expected to grow monotonically with the size of the substrate due to increased dispersion interactions, but interestingly, this is not the case here. This peculiar finding is explained using the static polarizabilities and molecular dispersion coefficients of the systems, as computed from time-dependent density functional theory (DFT). Dynamic as well as static polarizabilities are found to be highly anisotropic in these systems. In addition, the many-body dispersion method in DFT emerges as a particularly useful estimation of finite size effects for other expensive, many-body wavefunction based methods. [ABSTRACT FROM AUTHOR]

Published
2017
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26. Consistent structures and interactions by density functional theory with small atomic orbital basis sets.

Author

Grimme, Stefan, Brandenburg, Jan Gerit, Bannwarth, Christoph, and Hansen, Andreas

Subjects
*DENSITY functional theory, *GAUSSIAN basis sets (Quantum mechanics), *ATOMIC orbitals, *LONDON dispersion forces, *COMPOSITE materials, *ELECTRONIC structure
Abstract

A density functional theory (DFT) based composite electronic structure approach is proposed to efficiently compute structures and interaction energies in large chemical systems. It is based on the well-known and numerically robust Perdew-Burke-Ernzerhoff (PBE) generalized-gradientapproximation in a modified global hybrid functional with a relatively large amount of non-local Fock-exchange. The orbitals are expanded in Ahlrichs-type valence-double zeta atomic orbital (AO) Gaussian basis sets, which are available for many elements. In order to correct for the basis set superposition error (BSSE) and to account for the important long-range London dispersion effects, our well-established atom-pairwise potentials are used. In the design of the new method, particular attention has been paid to an accurate description of structural parameters in various covalent and non-covalent bonding situations as well as in periodic systems. Together with the recently proposed three-fold corrected (3c) Hartree-Fock method, the new composite scheme (termed PBEh-3c) represents the next member in a hierarchy of "low-cost" electronic structure approaches. They are mainly free of BSSE and account for most interactions in a physically sound and asymptotically correct manner. PBEh-3c yields good results for thermochemical properties in the huge GMTKN30 energy database. Furthermore, the method shows excellent performance for non-covalent interaction energies in small and large complexes. For evaluating its performance on equilibrium structures, a new compilation of standard test sets is suggested. These consist of small (light) molecules, partially flexible, medium-sized organic molecules, molecules comprising heavy main group elements, larger systems with long bonds, 3d-transition metal systems, non-covalently bound complexes (S22 and S66×8 sets), and peptide conformations. For these sets, overall deviations from accurate reference data are smaller than for various other tested DFT methods and reach that of triple-zeta AO basis set second-order perturbation theory (MP2/TZ) level at a tiny fraction of computational effort. Periodic calculations conducted for molecular crystals to test structures (including cell volumes) and sublimation enthalpies indicate very good accuracy competitive to computationally more involved plane-wave based calculations. PBEh-3c can be applied routinely to several hundreds of atoms on a single processor and it is suggested as a robust "high-speed" computational tool in theoretical chemistry and physics. [ABSTRACT FROM AUTHOR]

Published
2015
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27. Benchmarking DFT and semiempirical methods on structures and lattice energies for ten ice polymorphs.

Author

Brandenburg, Jan Gerit, Maas, Tilo, and Grimme, Stefan

Subjects
*DENSITY functional theory, *EMPIRICAL research, *MOLECULAR structure, *POLYMORPHISM (Crystallography), *CRYSTAL lattices, *WATER, *MOLECULAR orbitals
Abstract

Water in different phases under various external conditions is very important in bio-chemical systems and for material science at surfaces. Density functional theory methods and approximations thereof have to be tested system specifically to benchmark their accuracy regarding computed structures and interaction energies. In this study, we present and test a set of ten ice polymorphs in comparison to experimental data with mass densities ranging from 0.9 to 1.5 g/cm³ and including explicit corrections for zero-point vibrational and thermal effects. London dispersion inclusive density functionals at the generalized gradient approximation (GGA), meta-GGA, and hybrid level as well as alternative low-cost molecular orbital methods are considered. The widely used functional of Perdew, Burke and Ernzerhof (PBE) systematically overbinds and overall provides inconsistent results. All other tested methods yield reasonable to very good accuracy. BLYP-D3atm gives excellent results with mean absolute errors for the lattice energy below 1 kcal/mol (7% relative deviation). The corresponding optimized structures are very accurate with mean absolute relative deviations (MARDs) from the reference unit cell volume below 1%. The impact of Axilrod-Teller-Muto (atm) type three-body dispersion and of non-local Fock exchange is small but on average their inclusion improves the results. While the density functional tight-binding model DFTB3-D3 performs well for low density phases, it does not yield good high density structures. As low-cost alternative for structure related problems, we recommend the recently introduced minimal basis Hartree-Fock method HF-3c with a MARD of about 3%. [ABSTRACT FROM AUTHOR]

Published
2015
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29. New density-functional approximations and beyond: general discussion

Author

Brandenburg, Jan Gerit, primary, Burke, Kieron, additional, Cancio, Antonio, additional, Erhard, Jannis, additional, Fromager, Emmanuel, additional, Ghosal, Abhisek, additional, Gidopoulos, Nikitas, additional, Gori-Giorgi, Paola, additional, Helgaker, Trygve, additional, Hourahine, Ben, additional, Jacob, Christoph R., additional, Kooi, Derk, additional, Maitra, Neepa, additional, Mulay, Manasi R., additional, Pernal, Katarzyna, additional, Pribram-Jones, Aurora, additional, Reining, Lucia, additional, Romaniello, Pina, additional, Ryder, Matthew R., additional, Savin, Andreas, additional, Skylaris, Chris-Kriton, additional, Teale, Andrew M., additional, Tozer, David, additional, Truhlar, Donald G., additional, and Yang, Weitao, additional

Published
2020
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30. New approaches to study excited states in density functional theory: general discussion

Author

Brandenburg, Jan Gerit, primary, Burke, Kieron, additional, Fromager, Emmanuel, additional, Gatti, Matteo, additional, Giarrusso, Sara, additional, Gidopoulos, Nikitas I., additional, Gori-Giorgi, Paola, additional, Gowland, Duncan, additional, Helgaker, Trygve, additional, Hodgson, Matthew J. P., additional, Lacombe, Lionel, additional, Levi, Gianluca, additional, Loos, Pierre-François, additional, Maitra, Neepa T., additional, Maurina Morais, Eduardo, additional, Mehta, Nisha, additional, Monti, Filippo, additional, Mulay, Manasi R., additional, Pernal, Katarzyna, additional, Reining, Lucia, additional, Romaniello, Pina, additional, Ryder, Matthew R., additional, Savin, Andreas, additional, Sirbu, Dumitru, additional, Teale, Andrew M., additional, Thom, Alex J. W., additional, Truhlar, Donald G., additional, Wetherell, Jack, additional, and Yang, Weitao, additional

Published
2020
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31. Challenges for large scale simulation: general discussion

Author

Brandenburg, Jan Gerit, primary, Burke, Kieron, additional, Civalleri, Bartolomeo, additional, Cole, Daniel J., additional, Csányi, Gábor, additional, David, Grégoire, additional, Gidopoulos, Nikitas I., additional, Gowland, Duncan, additional, Helgaker, Trygve, additional, Herbst, Michael F., additional, Hourahine, Ben, additional, Irons, Tom J. P., additional, Jacob, Christoph R., additional, Loos, Pierre-François, additional, Mehta, Nisha, additional, Mulay, Manasi R., additional, Neugebauer, Johannes, additional, Pernal, Katarzyna, additional, Pribram-Jones, Aurora, additional, Romaniello, Pina, additional, Ryder, Matthew R., additional, Savin, Andreas, additional, Sirbu, Dumitru, additional, Skylaris, Chris-Kriton, additional, Truhlar, Donald G., additional, Wetherell, Jack, additional, and Yang, Weitao, additional

Published
2020
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35. Advances in Density-Functional Calculations for Materials Modeling

Author

Maurer, Reinhard, Freysoldt, Christoph, Reilly, Anthony, Brandenburg, Jan Gerit, Hofmann, Oliver, Björkman, Torbjörn, Lebègue, Sébastien, Tkatchenko, Alexandre, Maurer, Reinhard, Freysoldt, Christoph, Reilly, Anthony, Brandenburg, Jan Gerit, Hofmann, Oliver, Björkman, Torbjörn, Lebègue, Sébastien, and Tkatchenko, Alexandre

Abstract

During the past two decades, density-functional (DF) theory has evolved from niche applications for simple solid-state materials to become a workhorse method for studying a wide range of phenomena in a variety of system classes throughout physics, chemistry, biology, and materials science. Here, we review the recent advances in DF calculations for materials modeling, giving a classification of modern DF-based methods when viewed from the materials modeling perspective. While progress has been very substantial, many challenges remain on the way to achieving consensus on a set of universally applicable DF-based methods for materials modeling. Hence, we focus on recent successes and remaining challenges in DF calculations for modeling hard solids, molecular and biological matter, low-dimensional materials, and hybrid organic-inorganic materials.

Published
2019
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41. Structure and Stability of Molecular Crystals with Many-Body Dispersion-Inclusive Density Functional Tight Binding

Author

Mortazavi, Majid, Brandenburg, Jan Gerit, Maurer, Reinhard J., Tkatchenko, Alexandre, Mortazavi, Majid, Brandenburg, Jan Gerit, Maurer, Reinhard J., and Tkatchenko, Alexandre

Abstract

Accurate prediction of structure and stability of molecular crystals is crucial in materials science and requires reliable modeling of long-range dispersion interactions. Semiempirical electronic structure methods are computationally more efficient than their ab initio counterparts, allowing structure sampling with significant speedups. We combine the Tkatchenko−Scheffler van der Waals method (TS) and the many-body dispersion method (MBD) with third-order density functional tight-binding (DFTB3) via a charge population-based method. We find an overall good performance for the X23 benchmark database of molecular crystals, despite an underestimation of crystal volume that can be traced to the DFTB parametrization. We achieve accurate lattice energy predictions with DFT+MBD energetics on top of vdW-inclusive DFTB3 structures, resulting in a speedup of up to 3000 times compared with a full DFT treatment. This suggests that vdW-inclusive DFTB3 can serve as a viable structural prescreening tool in crystal structure prediction.

Published
2018

42. Report on the sixth blind test of organic crystal-structure prediction methods

Author

Reilly, Anthony M., Cooper, Richard I., Adjiman, Claire S., Bhattacharya, Saswate, Boese, A. Daniel, Brandenburg, Jan Gerit, Bygrave, Peter J., Bylsma, Rita, Campbell, Josh E., Car, Roberto, Case, David H., Chadha, Renu, Cole, Jason C., Cosburn, Katherine, Cuppen, Herma M., Curtis, Farren, Day, Graeme M., DiStasio Jr, Robert A., Dzyabchenko, Alexander, van Eijck, Bouke P., Elking, Dennis M., can den Ende, Joost A., Facelli, Julio C., Ferraro, Marta B., Fusti-Molnar, Laszlo, Gatsiou, Chritina-Anna, Gee, Thomas S., de Gelder, Rene, Ghiringhelli, Luca M., Goto, Hitoshi, Grimme, Stefan, Guo, Rui, Hofmann, Detlef W.M., Hoja, Johannes, Hylton, Rebecca K., Iuzzolino, Luca, Jankiewicz, Wojciech, de Jong, Daniel T., Kendrick, John, de Klerk, Niek J.J., Ko, Hsin-Yu, Kuleshova, Liudmila N., Li, Xiayue, Lohani, Sanjaya, Leusen, Frank J.J., Lund, Albert M., Lv, Jian, Ma, Yanming, Marom, Noa, Masunov, Artem E., McCabe, Patrick, McMahon, David P., Meekes, Hugo, Metz, Michael P., Misquitta, Alston J., Mohamed, Sharmarke, Monserrat, Bartomeu, Needs, Richard J., Neumann, Marcus A., Nyman, Jonas, Obata, Shigeaki, Oberhofer, Harald, Oganov, Artem R., Orendt, Anita M., Pagola, Gabriel I., Pantelides, Constantinos C., Pickard, Chris J., Podeszwa, Rafal, Price, Louise S., Price, Sarah L., Pulido, Angeles, Read, Murray G., Reuter, Karsten, Schneider, Elia, Schober, Christoph, Shields, Gregory P., Singh, Pawanpreet, Sugden, Isaac J., Szaleqicz, Krzysztof, Taylor, Christopher R., Tkatchenko, Alexandre, Tuckerman, Mark E., Vacarro, Francesca, Vasileiadis, Manolis, Vazquez-Mayagoitia, Alvaro, Vogt, Leslie, Wang, Yanchao, Watson, Rona E., de Wijs, Gilles A., Yang, Jack, Zhu, Qiang, and Groom, Colin R.

Abstract

The sixth blind test of organic crystal-structure prediction (CSP) methods has been held, with five target systems: a small nearly rigid molecule, a polymorphic former drug candidate, a chloride salt hydrate, a co-crystal, and a bulky flexible molecule. This blind test has seen substantial growth in the number of submissions, with the broad range of prediction methods giving a unique insight into the state of the art in the field. Significant progress has been seen in treating flexible molecules, usage of hierarchical approaches to ranking structures, the application of density-functional approximations, and the establishment of new workflows and "best practices" for performing CSP calculations. All of the targets, apart from a single potentially disordered Z` = 2 polymorph of the drug candidate, were predicted by at least one submission. Despite many remaining challenges, it is clear that CSP methods are becoming more applicable to a wider range of real systems, including salts, hydrates and larger flexible molecules. The results also highlight the potential for CSP calculations to complement and augment experimental studies of organic solid forms.

Published
2016

44. Applications of crystal structure prediction – organic molecular structures: general discussion

Author

Adjiman, Claire S., primary, Brandenburg, Jan Gerit, additional, Braun, Doris E., additional, Cole, Jason, additional, Collins, Christopher, additional, Cooper, Andrew I., additional, Cruz-Cabeza, Aurora J., additional, Day, Graeme M., additional, Dudek, Marta, additional, Hare, Alan, additional, Iuzzolino, Luca, additional, McKay, David, additional, Mitchell, John B. O., additional, Mohamed, Sharmarke, additional, Neelamraju, Sridhar, additional, Neumann, Marcus, additional, Nilsson Lill, Sten, additional, Nyman, Jonas, additional, Oganov, Artem R., additional, Price, Sarah L., additional, Pulido, Angeles, additional, Reutzel-Edens, Susan, additional, Rietveld, Ivo, additional, Ruggiero, Michael T., additional, Schön, J. Christian, additional, Tsuzuki, Seiji, additional, van den Ende, Joost, additional, Woollam, Grahame, additional, and Zhu, Qiang, additional

Published
2018
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46. Solid state frustrated Lewis pair chemistry

Author

Wang, Long, primary, Kehr, Gerald, additional, Daniliuc, Constantin G., additional, Brinkkötter, Melanie, additional, Wiegand, Thomas, additional, Wübker, Anna-Lena, additional, Eckert, Hellmut, additional, Liu, Lei, additional, Brandenburg, Jan Gerit, additional, Grimme, Stefan, additional, and Erker, Gerhard, additional

Published
2018
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47. Crystal structure evaluation: calculating relative stabilities and other criteria: general discussion

Author

Addicoat, Matthew, primary, Adjiman, Claire S., additional, Arhangelskis, Mihails, additional, Beran, Gregory J. O., additional, Bowskill, David, additional, Brandenburg, Jan Gerit, additional, Braun, Doris E., additional, Burger, Virginia, additional, Cole, Jason, additional, Cruz-Cabeza, Aurora J., additional, Day, Graeme M., additional, Deringer, Volker L., additional, Guo, Rui, additional, Hare, Alan, additional, Helfferich, Julian, additional, Hoja, Johannes, additional, Iuzzolino, Luca, additional, Jobbins, Samuel, additional, Marom, Noa, additional, McKay, David, additional, Mitchell, John B. O., additional, Mohamed, Sharmarke, additional, Neumann, Marcus, additional, Nilsson Lill, Sten, additional, Nyman, Jonas, additional, Oganov, Artem R., additional, Piaggi, Pablo, additional, Price, Sarah L., additional, Reutzel-Edens, Susan, additional, Rietveld, Ivo, additional, Ruggiero, Michael, additional, Ryder, Matthew R., additional, Sastre, German, additional, Schön, J. Christian, additional, Taylor, Christopher, additional, Tkatchenko, Alexandre, additional, Tsuzuki, Seiji, additional, van den Ende, Joost, additional, Woodley, Scott M., additional, Woollam, Grahame, additional, and Zhu, Qiang, additional

Published
2018
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48. Structure searching methods: general discussion

Author

Addicoat, Matthew, primary, Adjiman, Claire S., additional, Arhangelskis, Mihails, additional, Beran, Gregory J. O., additional, Brandenburg, Jan Gerit, additional, Braun, Doris E., additional, Burger, Virginia, additional, Burow, Asbjoern, additional, Collins, Christopher, additional, Cooper, Andrew, additional, Day, Graeme M., additional, Deringer, Volker L., additional, Dyer, Matthew S, additional, Hare, Alan, additional, Jelfs, Kim E., additional, Keupp, Julian, additional, Konstantinopoulos, Stefanos, additional, Li, Yi, additional, Ma, Yanming, additional, Marom, Noa, additional, McKay, David, additional, Mellot-Draznieks, Caroline, additional, Mohamed, Sharmarke, additional, Neumann, Marcus, additional, Nilsson Lill, Sten, additional, Nyman, Jonas, additional, Oganov, Artem R., additional, Price, Sarah L., additional, Reutzel-Edens, Susan, additional, Ruggiero, Michael, additional, Sastre, German, additional, Schmid, Rochus, additional, Schmidt, Julia, additional, Schön, J. Christian, additional, Spackman, Peter, additional, Tsuzuki, Seiji, additional, Woodley, Scott M., additional, Yang, Shiyue, additional, and Zhu, Qiang, additional

Published
2018
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