Your search keyword '"ab initio"' showing total 82,394 results

1. Cooperativity and halonium transfer in the ternary NCI···CH3I···−CN halogen-bonded complex: An ab initio gas phase study.

Author

Parra, Rubén D.

Abstract

Context: The strength and nature of the two halogen bonds in the NCI···CH3I···−CN halogen-bonded ternary complex are studied in the gas phase via ab initio calculations. Different indicators of halogen bond strength were employed to examine the interactions including geometries, complexation energies, Natural Bond Order (NBO) Wiberg bond indices, and Atoms in Molecules (AIM)-based charge density topological properties. The results show that the halogen bond is strong and partly covalent in nature when CH3I donates the halogen bond, but weak and noncovalent in nature when CH3I accepts the halogen bond. Significant halogen bond cooperativity emerges in the ternary complex relative to the corresponding heterodimer complexes, NCI···CH3I and CH3I···−CN, respectively. For example, the CCSD(T) complexation energy of the ternary complex (-18.27 kcal/mol) is about twice the sum of the complexation energies of the component dimers (-9.54 kcal/mol). The halonium transfer reaction that converts the ternary complex into an equivalent one was also investigated. The electronic barrier for the halonium transfer was calculated to be 6.70 kcal/mol at the CCSD(T) level. Although the MP2 level underestimates and the MP3 overestimates the barrier, their calculated MP2.5 average barrier (6.44 kcal/mol) is close to that of the more robust CCSD(T) level. Insights on the halonium ion transfer reaction was obtained by examining the reaction energy and force profiles along the intrinsic reaction coordinate, IRC. The corresponding evolution of other properties such as bond lengths, Wiberg bond indices, and Mulliken charges provides specific insight on the extent of structural rearrangements and electronic redistribution throughout the entire IRC space. Methods: The MP2 method was used for geometry optimizations. Energy calculations were performed using the CCSD(T) method. The aug-cc-pVTZ basis set was employed for all atoms other than iodine for which the aug-cc-pVTZ-PP basis set was used instead. [ABSTRACT FROM AUTHOR]

Published

2024

2. Exploring Unconventional Electron Distribution Patterns: Contrasts Between FeSe and FeSe/STO Using an Ab Initio Approach.

Author

Wong, Chi-Ho and Lortz, Rolf

Subjects

*CHARGE density waves, *PHOTOELECTRON spectroscopy, *ELECTRON distribution, *FERMI level, *SUPERCONDUCTIVITY, *IRON-based superconductors

Abstract

For more than a decade, the unusual distribution of electrons observed in ARPES (angle-resolved photoemission spectroscopy) data within the energy range of ~30 meV to ~300 meV below the Fermi level, known as the ARPES energy range, has remained a puzzle in the field of iron-based superconductivity. As the electron–phonon coupling of FeSe/SrTiO3 is very strong, our investigation is centered on exploring the synergistic interplay between spin-density waves (SDW) and charge-density waves (CDW) with differential phonons at the interface between antiferromagnetic maxima and minima under wave interference. Our analysis reveals that the synergistic energy is proportional to the ARPES energy range, as seen in the comparison between FeSe and FeSe/SrTiO3. This finding may suggest that the instantaneous interplay between these intricate phenomena may play a role in triggering the observed energy range in ARPES. [ABSTRACT FROM AUTHOR]

Published

2024

3. Terms of Latin origin relating to sample characterization (IUPAC Technical Report).

Author

Peterson, Vanessa K., Bianchini, Matteo, Chapman, Karena W., Elice, Martina, Hibbert, David Brynn, Roche, Paul, Silvano, Luigi, and Stievano, Lorenzo

Subjects

*SCIENTIFIC literature, *TECHNICAL reports

Abstract

The use of Latin origin terms, relevant for sample characterization modalities, is described with a focus on samples under controlled conditions, samples within devices, and samples during physico-chemical evolution. The terms in vitro, in vivo, in situ, ab initio, in silico, post mortem, ex situ, posthumous, in vacuo, (in) operando, post facto, and ex post facto, as used in the scientific literature, are considered. Uses of the Latin origin terms in situ, extra situm, in operando, in vivo, in vacuo, in vitro, extra vivum, post facto and ex post facto, ab initiis, computatro, and post mortem are discussed. It is suggested that these terms are to be used without hyphenation and that all Latin derived terms are set in italic font. [ABSTRACT FROM AUTHOR]

Published

2024

4. Equilibrium Structures of Propane and 2,2-Difluoropropane and Comparison with Other Two-Top Molecules.

Author

Demaison, Jean, Vogt, Natalja, and Perrin, Agnès

Subjects

*ATOMS in molecules theory, *PROPANE, *EQUILIBRIUM

Abstract

The Born–Oppenheimer ab initio equilibrium structures of propane (CH3)2CH2 and 2,2-difluoropropane (CH3)2CF2 were computed at the CCSD(T) level of theory using a basis set of quadruple zeta quality. The semiexperimental structure of propane was also determined from the ground state rotational constants corrected for rovibrational corrections calculated at the MP2 level of theory. Structural comparisons are made with other molecules and are discussed in terms of the quantum theory of atoms in molecules. [ABSTRACT FROM AUTHOR]

Published

2024

5. Trends in the Reactivity of Pentacyclic Ether Derivatives on Silicon and Germanium Surfaces Revealed by Energy Decomposition Analysis for Extended Systems.

Author

Thiemann, Franz, Weiske, Hendrik, and Tonner‐Zech, Ralf

Subjects

*ETHER derivatives, *COORDINATE covalent bond, *SILICON surfaces, *BOUND states, *BOND strengths

Abstract

We analyze the adsorption and ring‐opening reaction of pentacyclic chalcogen alkyls with chalcogen atoms ranging from oxygen to tellurium using computational analysis. Thus extends our previous investigation of THF on silicon towards germanium surface and towards the heavier chalcogen homologues. We found an increasing dative bond strength of the precursor state with the period of the chalcogen atom on both surfaces. Using energy decomposition analysis for extended systems (pEDA), differences in the trends between silicon and germanium were revealed. Following the dative bound state, subsequent ring‐opening reactions were found to proceed via a nucleophilic back‐side attack, similar to a molecular SN2 reaction. Reaction energies and barrier heights show a maximum for the sulfur derivative. This trend was found to correlate with the position of the transition state in the reaction and agrees with the molecular reactivity. The uniquely low barrier of THF can be attributed to its ring strain. Our findings shed light on the fundamental aspects of surface chemistry and the benefits of using quantitative bonding analysis in this field. It also paves the way for future explorations into the functionalization of semiconductor surfaces using higher‐period ether derivatives. [ABSTRACT FROM AUTHOR]

Published

2024

6. Interpretation of molecular electron transport in ab initio many‐electron framework incorporating zero‐point nuclear motion effects.

Author

Jelenfi, Dávid P., Tajti, Attila, and Szalay, Péter G.

Subjects

*CAPABILITIES approach (Social sciences), *MOLECULAR vibration, *ELECTRON transport, *PROBABILITY theory, *TRANSMISSION of sound

Abstract

A computational methodology, founded on chemical concepts, is presented for interpreting the role of nuclear motion in the electron transport through single‐molecule junctions (SMJ) using many‐electron ab initio quantum chemical calculations. Within this approach the many‐electron states of the system, computed at the SOS‐ADC(2) level, are followed along the individual normal modes of the encapsulated molecules. The inspection of the changes in the partial charge distribution of the many‐electron states allows the quantification of the electron transport and the estimation of transmission probabilities. This analysis improves the understanding of the relationship between internal motions and electron transport. Two SMJ model systems are studied for validation purposes, constructed from a conductor (BDA, benzene‐1,4‐diamine) and an insulator molecule (DABCO, 1,4‐diazabicyclo[2.2.2]octane). The trends of the resulting transmission probabilities are in agreement with the experimental observations, demonstrating the capability of the approach to distinguish between conductor and insulator type systems, thereby offering a straightforward and cost‐effective tool for such classifications via quantum chemical calculations. [ABSTRACT FROM AUTHOR]

Published

2024

7. A theoretical study on excited-state dynamical properties and laser cooling of zinc monohydride including spin-orbit couplings.

Author

Li, Donghui, Fayyaz, Faiza, Bian, Wensheng, Chen, Jun, and Bhowmick, Somnath

Subjects

*SPIN-orbit interactions, *MOLECULAR gas lasers, *LASER cooling, *LASERS, *AB-initio calculations, *TRANSITION metal alloys

Abstract

By means of highly accurate ab initio and dynamical calculations, we identify a suitable laser cooling candidate that contains a transition metal element, namely zinc monohydride (ZnH). The internally contracted multireference configuration interaction method is employed to compute the five lowest-lying Λ-S states of ZnH with the spin-orbit coupling effects included, and very good agreement is obtained between our calculated and experimental spectroscopic data. Our findings show that the position of crossing point of the A2Π and B2Σ+ states of ZnH is above the v' = 2 vibrational level of the A2n state indicating that the crossings with higher electronic states will have no effect on laser cooling. Hence, we construct a feasible laser-cooling scheme for ZnH using five lasers based on the A2Π1/2 → X2Σ+ 1/2 transition, which features a large vibrational branching ratio R00 (0.8458), a large number of scattered photons (9.8 × 103) and an extremely short radiative lifetime (64 ns). The present work demonstrates the importance of electronic state crossings and spin-orbit couplings in the study of molecular laser cooling. [ABSTRACT FROM AUTHOR]

Published

2024

8. Ab Initio Investigation of the Hydration of the Tetrahedral d 0 Transition Metal Oxoanions NbO 4 3− , TaO 4 3− , CrO 4 2− , MoO 4 2− , WO 4 2− , MnO 4 − , TcO 4 − , ReO 4 − , and of FeO 4 , RuO 4 , and OsO 4

Author

Goodall, Barbara L., Ferguson, Jane P., and Pye, Cory C.

Subjects

TETRAHEDRA, HYDRATION, CHEMICALS, SOLVENTS, ORGANIC compounds

Abstract

The geometries and vibrational frequencies of various configurations of XO4m−(H2O)n, X = Fe, Ru, Os, m = 0; X = Mn, Tc, Re, m = 1; X = Cr, Mo, W, m = 2; and X = Nb, Ta, m = 3; n = 0–6 are calculated at various levels up to MP2/6-31+G* and B3LYP/6-31+G*. These properties are studied as a function of increasing cluster size. The experimental and theoretical bond distances and vibrational spectra are compared where available, and predictions are made where they are not. [ABSTRACT FROM AUTHOR]

Published

2024

9. Magnetocaloric effect, magnetothermal and elastic properties of SmFe3 and ErFe3 compounds.

Author

Mohammad, Fatema Z., Abdel-Kader, Ahmed, Hammad, Tarek, Yehia, Sherif, Aly, Samy H., and Abu-Elmagd, Mohammed Said Mohammed

Abstract

We report on the temperature and field dependences of magnetization, magnetic specific heat, and magnetic entropy of the ferromagnetic SmFe 3 ( T C ≈ 655 K) and ferrimagnetic ErFe 3 ( T C ≈ 600 K, compensation temperature ≈ 230 K) compounds using the mean-field theory (MFT). The magnetocaloric effect (MCE), namely, the isothermal change in entropy (∆Sm) and the adiabatic change in temperature (∆Tad), is determined using the well-known Maxwell relation. Density Functional Theory (DFT), as implemented in the WIEN2k electronic code, is used to perform the ab-initio calculation of the elastic constants, bulk and shear moduli, and density-of-states. Using the electronic coefficient of specific heat ( γ e ) and the Debye temperature ( θ D ), the electronic and lattice contributions to the total specific heat and total entropy are computed, respectively. The ferrimagnetic ErFe 3 exhibits both direct and inverse MCE, while SmFe 3 exhibits only direct MCE effects. For SmFe 3 , the maximum Δ S m for a 7T field change is approximately 1.29 J/mol K. For the same field change, the maximum direct and inverse | Δ S m | for ErFe 3 are approximately 0.69 and 0.74 J/mol K, respectively. At their respective Curie temperatures, SmFe3 and ErFe3 exhibit adiabatic temperature changes of about 8 and 5 K, respectively, for a 7 T field change. The Arrott plots and universal curves, along with specific aspects of the thermomagnetic and magnetocaloric properties, are used to examine the order of the magnetic phase transition in these two systems. [ABSTRACT FROM AUTHOR]

Published

2024

10. Ab Initio Investigation of the Hydration of the Tetrahedral d0 Transition Metal Oxoanions NbO43−, TaO43−, CrO42−, MoO42−, WO42−, MnO4−, TcO4−, ReO4−, and of FeO4, RuO4, and OsO4

Author

Barbara L. Goodall, Jane P. Ferguson, and Cory C. Pye

Subjects

ab initio, density functional, vibrational spectra, tetrahedral oxoanions, hydration, Organic chemistry, QD241-441

Abstract

The geometries and vibrational frequencies of various configurations of XO4m−(H2O)n, X = Fe, Ru, Os, m = 0; X = Mn, Tc, Re, m = 1; X = Cr, Mo, W, m = 2; and X = Nb, Ta, m = 3; n = 0–6 are calculated at various levels up to MP2/6-31+G* and B3LYP/6-31+G*. These properties are studied as a function of increasing cluster size. The experimental and theoretical bond distances and vibrational spectra are compared where available, and predictions are made where they are not.

Published

2024

11. Influence of co-sputtering AlB2 to TaB2 on stoichiometry of non-reactively sputtered boride thin films

Author

Chun Hu, Shuyao Lin, M. Podsednik, Stanislav Mráz, T. Wojcik, A. Limbeck, Nikola Koutná, and Paul H. Mayrhofer

Subjects

Stoichiometry, diboride thin films, hardness, microstructure, Ab initio, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Transition metal diboride thin films are promising functional materials for their outstanding mechanical properties and thermal stability. By combining experiment and simulations, we discuss angular distribution of the sputtered species, their scattering in the gas phase, re-sputtering and potential evaporation from the grown films for the complex evolution of film compositions, as well as energetic preference for vacancy formation and competing phases as factors for governing the phase constitution. By co-sputtering from two compound targets, we developed phase-pure crystalline (Ta,Al)B2 solid solution thin films and correlate the stoichiometry changes with the evolution of their microstructure, hardness, and elastic modulus.

Published

2024

12. Tellurene Polymorphs: A New Frontier for Solar Harvesting with Strong Exciton Anisotropy and High Optical Absorbance.

Author

Grillo, Simone, Postorino, Sara, Palummo, Maurizia, and Pulci, Olivia

Subjects

*PERTURBATION theory, *SEMICONDUCTORS, *DENSITY functional theory, *EXCITON theory, *TELLURIUM

Abstract

By using ab initio simulations based on density functional theory and many‐body perturbation theory, a comprehensive analysis of the distinct optical signatures of various tellurene polymorphs and their associated unique anisotropic excitonic characteristics is presented. Despite the atomic thickness of these materials, these findings reveal that their optical absorbance reaches as high as 50% in the near‐infrared and visible range. This investigation highlights the exceptional potential of these 2D semiconducting materials in the development of ultra‐thin and flexible homo‐ and hetero‐junctions for solar light harvesting, achieving photoconversion efficiencies up to 19%, a performance level comparable to current silicon technologies. [ABSTRACT FROM AUTHOR]

Published

2024

13. Ab Initio Molecular Dynamics Insight to Structural Phase Transition and Thermal Decomposition of InN.

Author

Piechota, Jacek, Krukowski, Stanislaw, Sadovyi, Bohdan, Sadovyi, Petro, Porowski, Sylwester, and Grzegory, Izabella

Subjects

*PHASE transitions, *INDIUM nitride, *DENSITY functional theory, *MOLECULAR dynamics, *STRUCTURAL dynamics

Abstract

Extensive ab initio density functional theory molecular dynamics calculations were used to evaluate stability conditions for relevant phases of InN. In particular, the p-T conditions of the thermal decomposition of InN and pressure-induced wurtzite–rocksalt solid–solid phase transition were established. The comparison of the simulation results with the available experimental data allowed for a critical evaluation of the capabilities and limitations of the proposed simulation method. It is shown that ab initio molecular dynamics can be used as an efficient tool for simulations of phase transformations of InN, including solid–solid structural transition and thermal decomposition with formation of N2 molecules. It is of high interest, because InN is an important component of epitaxial quantum structures, but it has not been obtained as a bulk single crystal. This makes it difficult to determine its basic physical properties to develop new applications. [ABSTRACT FROM AUTHOR]

Published

2024

14. Influence of co-sputtering AlB2 to TaB2 on stoichiometry of non-reactively sputtered boride thin films.

Author

Hu, Chun, Lin, Shuyao, Podsednik, M., Mráz, Stanislav, Wojcik, T., Limbeck, A., Koutná, Nikola, and Mayrhofer, Paul H.

Subjects

THIN films, MECHANICAL behavior of materials, EVAPORATIVE power, ANGULAR distribution (Nuclear physics), BORIDES, ELASTIC modulus, EVAPORATION (Chemistry), STOICHIOMETRY

Abstract

Transition metal diboride thin films are promising functional materials for their outstanding mechanical properties and thermal stability. By combining experiment and simulations, we discuss angular distribution of the sputtered species, their scattering in the gas phase, re-sputtering and potential evaporation from the grown films for the complex evolution of film compositions, as well as energetic preference for vacancy formation and competing phases as factors for governing the phase constitution. By co-sputtering from two compound targets, we developed phase-pure crystalline (Ta,Al)B2 solid solution thin films and correlate the stoichiometry changes with the evolution of their microstructure, hardness, and elastic modulus. [ABSTRACT FROM AUTHOR]

Published

2024

15. A Globally Accurate Neural Network Potential Energy Surface and Quantum Dynamics Studies on Be + (2 S) + H 2 /D 2 → BeH + /BeD + + H/D Reactions.

Author

Yang, Zijiang, Cao, Furong, Cheng, Huiying, Liu, Siwen, and Sun, Jingchang

Subjects

*ARTIFICIAL neural networks, *POTENTIAL energy surfaces, *QUANTUM theory, *WAVE packets, *SURFACE dynamics

Abstract

Chemical reactions between Be+ ions and H2 molecules have significance in the fields of ultracold chemistry and astrophysics, but the corresponding dynamics studies on the ground-state reaction have not been reported because of the lack of a global potential energy surface (PES). Herein, a globally accurate ground-state BeH2+ PES is constructed using the neural network model based on 18,657 ab initio points calculated by the multi-reference configuration interaction method with the aug-cc-PVQZ basis set. On the newly constructed PES, the state-to-state quantum dynamics calculations of the Be+(2S) + H2(v0 = 0; j0 = 0) and Be+(2S) + D2(v0 = 0; j0 = 0) reactions are performed using the time-dependent wave packet method. The calculated results suggest that the two reactions are dominated by the complex-forming mechanism and the direct abstraction process at relatively low and high collision energies, respectively, and the isotope substitution has little effect on the reaction dynamics characteristics. The new PES can be used to further study the reaction dynamics of the BeH2+ system, such as the effects of rovibrational excitations and alignment of reactant molecules, and the present dynamics data could provide an important reference for further experimental studies at a finer level. [ABSTRACT FROM AUTHOR]

Published

2024

16. Determining Structures of Layer‐by‐Layer Spin‐Coated Zinc Dicarboxylate‐Based Metal‐Organic Thin Films.

Author

Fischer, Jan C., Steentjes, Robbin, Chen, Dong‐Hui, Richards, Bryce S., Zojer, Egbert, Wöll, Christof, and Howard, Ian A.

Subjects

*THIN films, *ZINC, *METALLIC films, *CRYSTALS, *DENSITY functional theory, *X-ray scattering, *COPPER-zinc alloys

Abstract

Thin films of crystalline solids with substantial free volume built from organic chromophores and metal secondary building units (SBUs) are promising for engineering new optoelectronic properties through control of interchromophore coupling. Zn‐based SBUs are especially relevant in this case because they avoid quenching the chromophore's luminescence. We find that layer‐by‐layer spin‐coating using Zn acetate dihydrate and benzene‐1,4‐dicarboxylic acid (H2BDC) and biphenyl‐4,4'‐dicarboxylic acid (H2BPDC) linkers readily produces crystalline thin films. However, analysis of the grazing‐incidence wide‐angle X‐ray scattering (GIWAXS) data reveals the structures of these films vary significantly with the linker, and with the metal‐to‐linker molar ratio used for fabrication. Under equimolar conditions, H2BPDC creates a type of structure like that proposed for SURMOF‐2, whereas H2BDC generates a different metal‐hydroxide‐organic framework. Large excess of Zn2+ ions causes the growth of layered zinc hydroxides, irrespective of the linker used. Density functional theory (DFT) calculations provide structural models with minimum total energy that are consistent with the experimentally observed diffractograms. In the broader sense, this work illustrates the importance in this field of careful structure determination, e. g., by utilizing GIWAXS and DFT simulations to determine the structure of the obtained crystalline metal‐organic thin films, such that properties can be rationally engineered and explained. [ABSTRACT FROM AUTHOR]

Published

2024

17. Equilibrium Values for the Si-H Bond Length and Equilibrium Structures of Silyl Iodide and Halosilylenes

Author

Demaison, Jean and Liévin, Jacques

Abstract

The equilibrium structures of silyl iodide, SiH3I, and silylene halides, SiHX (X = F, Cl, Br, I), were determined by using the mixed regression method, where approximate values of the rotational constants are supplemented by the structural parameters of a different origin. For this goal, it is shown that the r(Si-H) bond length can be determined by using the isolated SiH stretching frequency and that an accurate estimation of the bond angles is obtained by an MP2 calculation with a basis set of triple zeta quality. To check the accuracy of the experimental structures, they were also optimized by means of all electron CCSD(T) calculations using basis sets of quadruple zeta quality. [ABSTRACT FROM AUTHOR]

Published

2024

18. Ab Initio Modelling of g -ZnO Deposition on the Si (111) Surface.

Author

Alzhanova, Aliya, Mastrikov, Yuri, and Yerezhep, Darkhan

Subjects

ELECTRON density, ZINC oxide, SUBSTRATES (Materials science), DENSITY of states, COMPUTER simulation

Abstract

Recent studies show that zinc oxide (ZnO) nanostructures have promising potential as an absorbing material. In order to improve the optoelectronic properties of the initial system, this paper considers the process of adsorbing multilayer graphene-like ZnO onto a Si (111) surface. The density of electron states for two- and three-layer graphene-like zinc oxide on the Si (111) surface was obtained using the Vienna ab-initio simulation package by the DFT method. A computer model of graphene-like Zinc oxide on a Si (111)-surface was created using the DFT+U approach. One-, two- and three-plane-thick graphene-zinc oxide were deposited on the substrate. An isolated cluster of Zn3O3 was also considered. The compatibility of g-ZnO with the S (100) substrate was tested, and the energetics of deposition were calculated. This study demonstrates that, regardless of the possible configuration of the adsorbing layers, the Si/ZnO structure remains stable at the interface. Calculations indicate that, in combination with lower formation energies, wurtzite-type structures turn out to be more stable and, compared to sphalerite-type structures, wurtzite-type structures form longer interlayers and shorter interplanar distances. It has been shown that during the deposition of the third layer, the growth of a wurtzite-type structure becomes exothermic. Thus, these findings suggest a predictable relationship between the application method and the number of layers, implying that the synthesis process can be modified. Consequently, we believe that such interfaces can be obtained through experimental synthesis. [ABSTRACT FROM AUTHOR]

Published

2024

19. Influence of Sc, Y, Ti, Zr, Hf, V, Nb, and Ta on Structural and Mechanical Properties of Cr-Al-N Coatings.

Author

Mayrhofer, Paul H., Zhou, Liangcai, and Holec, David

Abstract

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Published

2024

20. Unraveling redox pathways of the disulfide bond in dimethyl disulfide: Ab initio modeling.

Author

Ould Mohamed, Lina, Abtouche, Soraya, Ghoualem, Zeyneb, and Assfeld, Xavier

Subjects

*ETHANES, *MOLECULAR dynamics, *REDUCTION potential, *ELECTRON capture, *MOLECULAR orbitals

Abstract

Context: In cellular environments, the reduction of disulfide bonds is pivotal for protein folding and synthesis. However, the intricate enzymatic mechanisms governing this process remain poorly understood. This study addresses this gap by investigating a disulfide bridge reduction reaction, serving as a model for comprehending electron and proton transfer in biological systems. Six potential mechanisms for reducing the dimethyl disulfide (DMDS) bridge through electron and proton capture were explored. Thermodynamic and kinetic analyses elucidated the sequence of proton and electron addition. MD-PMM, a method that combines molecular dynamics simulations and quantum-chemical calculations, was employed to compute the redox potential of the mechanism. This research provides valuable insights into the mechanisms and redox potentials involved in disulfide bridge reduction within proteins, offering an understanding of phenomena that are challenging to explore experimentally. Methods: All calculations used the Gaussian 09 software package at the MP2/6–311 + g(d,p) theory level. Visualization of the molecular orbitals and electron densities was conducted using Gaussview6. Molecular dynamics simulations were performed using GROMACS with the CHARMM36 force field. The PyMM program (Python Program for QM/MM Simulations Based on the Perturbed Matrix Method) is used to apply the Perturbed Matrix Method to MD simulations. [ABSTRACT FROM AUTHOR]

Published

2024

21. An Ab Initio Investigation of the Hydration of Antimony(III).

Author

Pye, Cory C. and Gunasekara, Champika Mahesh

Subjects

ANTIMONY, HYDRATION, CRYSTAL structure, HARTREE-Fock approximation, VIBRATIONAL spectra

Abstract

The energies, structures, and vibrational frequencies of [Sb(H2O)n]3+, n = 0–9, 18 have been calculated at the Hartree–Fock and second-order Møller–Plesset levels of theory using the CEP, LANL2, and SDD effective core potentials in combination with their associated basis sets, or with the 6-31G* and 6-31+G* basis sets. The metal–oxygen distances and totally symmetric stretching frequency of the aqua ions were compared with each other and with related crystal structure measurements where available. [ABSTRACT FROM AUTHOR]

Published

2024

22. Co-designing ab initio electronic structure methods on a RISC-V vector architecture [version 3; peer review: 4 approved]

Author

Rogeli Grima Torres, Pablo Vizcaíno, José Julio Gutiérrez Moreno, and Filippo Mantovani

Subjects

High-performance computing, co-design, ab initio, RISC-V, materials science, eigensolver library, eng, Science, Social Sciences

Abstract

Ab initio electronic structure applications are among the most widely used in High-Performance Computing (HPC), and the eigenvalue problem is often their main computational bottleneck. This article presents our initial efforts in porting these codes to a RISC-V prototype platform leveraging a wide Vector Processing Unit (VPU). Our software tester is based on a mini-app extracted from the ELPA eigensolver library. The user-space emulator Vehave and a RISC-V vector architecture implemented on an FPGA were tested. Metrics from both systems and different vectorisation strategies were extracted, ranging from the simplest and most portable one (using autovectorisation and assisting this by fusing loops in the code) to the more complex one (using intrinsics). We observed a progressive reduction in the number of vectorised instructions, executed instructions and computing cycles with the different methodologies, which will lead to a substantial speed-up in the calculations. The obtained outcomes are crucial in advancing the porting of computational materials and molecular science codes to (post)-exascale architectures using RISC-V-based technologies fully developed within the EU. Our evaluation also provides valuable feedback for hardware designers, engineers and compiler developers, making this use case pivotal for co-design efforts.

Published

2024

23. Ab initio calculations of anomalous seniority breaking in the πg9/2 shell for the N = 50 isotones

Author

Q. Yuan and B.S. Hu

Subjects

Ab initio, Chiral nuclear force, Seniority breaking, Cross-shell excitations, N=50 isotones, Physics, QC1-999

Abstract

We performed ab initio valence-space in-medium similarity renormalization group (VS-IMSRG) calculations based on chiral two-nucleon and three-nucleon interactions to investigate the anomalous seniority breaking in the neutron number N=50 isotones: 92Mo, 94Ru, 96Pd, and 98Cd. Our calculations well reproduced the measured low-lying spectra and electromagnetic E2 transitions in these nuclei, supporting partial seniority conservation in the first πg9/2 shell. Recent experiments have revealed that, compared to the symmetric patterns predicted under the conserved seniority symmetry, the 41+→21+ E2 transition strength in 94Ru is significantly enhanced and that in 96Pd is suppressed. In contrast, the 61+→41+ and 81+→61+ transitions exhibit the opposite trend. We found that this anomalous asymmetry is sensitive to subtle seniority breaking effects, providing a stringent test for state-of-the-art nucleon-nucleon interactions and nuclear models. We analyzed the anomalous asymmetry using VS-IMSRG calculations across various valence spaces. Our ab initio results suggest that core excitations of both proton and neutron across the Z=50 shell are ascribed to the observed anomalous seniority breaking in the N=50 isotones.

Published

2024

24. Co-designing ab initio electronic structure methods on a RISC-V vector architecture [version 2; peer review: 3 approved, 1 approved with reservations]

Author

Rogeli Grima Torres, Pablo Vizcaíno, José Julio Gutiérrez Moreno, and Filippo Mantovani

Subjects

High-performance computing, co-design, ab initio, RISC-V, materials science, eigensolver library, eng, Science, Social Sciences

Abstract

Ab initio electronic structure applications are among the most widely used in High-Performance Computing (HPC), and the eigenvalue problem is often their main computational bottleneck. This article presents our initial efforts in porting these codes to a RISC-V prototype platform leveraging a wide Vector Processing Unit (VPU). Our software tester is based on a mini-app extracted from the ELPA eigensolver library. The user-space emulator Vehave and a RISC-V vector architecture implemented on an FPGA were tested. Metrics from both systems and different vectorisation strategies were extracted, ranging from the simplest and most portable one (using autovectorisation and assisting this by fusing loops in the code) to the more complex one (using intrinsics). We observed a progressive reduction in the number of vectorised instructions, executed instructions and computing cycles with the different methodologies, which will lead to a substantial speed-up in the calculations. The obtained outcomes are crucial in advancing the porting of computational materials and molecular science codes to (post)-exascale architectures using RISC-V-based technologies fully developed within the EU. Our evaluation also provides valuable feedback for hardware designers, engineers and compiler developers, making this use case pivotal for co-design efforts.

Published

2024

25. How do mirror charge radii constrain density dependence of the symmetry energy?

Author

Bai-Shan Hu

Subjects

Ab initio, Chiral effective field theory, Charge radius difference of mirror nuclei, Neutron skin, Symmetry energy, Isospin-symmetry breaking, Physics, QC1-999

Abstract

It has recently been suggested that differences in the charge radii of mirror nuclei (ΔRchmirr) are strongly correlated with the neutron-skin thickness (Rskin) of neutron-rich nuclei and with the slope of the symmetry energy (L). To test this assumption, we present ab initio calculations of Rskin in 48Ca and 208Pb, ΔRchmirr in 36Ca−36S, 38Ca−38Ar, 41Sc−41Ca, 48Ni−48Ca, 52Ni−52Cr, and 54Ni−54Fe mirror pairs, and L. Employing the recently developed 34 chiral interaction samples, identified by the history matching approach, we conduct rigorous statistical analysis of correlations among ΔRchmirr, Rskin and L, accounting for quantified uncertainties from low-energy constants of chiral interaction, chiral effective field theory truncation and many-body method approximation. The ab initio results reveal an appreciable ΔRchmirr−L correlation in fp-shell mirror pairs. However, contrary to previous studies, the present calculation finds that the studied sd-shell mirror pairs do not exhibit any ΔRchmirr−L correlation.

Published

2024

26. An Ab Initio Investigation of the Hydration of Antimony(III)

Author

Cory C. Pye and Champika Mahesh Gunasekara

Subjects

ab initio, antimony(III), hydration, symmetry, vibrational spectrum, Organic chemistry, QD241-441

Abstract

The energies, structures, and vibrational frequencies of [Sb(H2O)n]3+, n = 0–9, 18 have been calculated at the Hartree–Fock and second-order Møller–Plesset levels of theory using the CEP, LANL2, and SDD effective core potentials in combination with their associated basis sets, or with the 6-31G* and 6-31+G* basis sets. The metal–oxygen distances and totally symmetric stretching frequency of the aqua ions were compared with each other and with related crystal structure measurements where available.

Published

2024

27. Extracting the electronic structure signal from X-ray and electron scattering in the gas phase

Author

Thomas Northey, Adam Kirrander, and Peter M. Weber

Subjects

x-ray scattering, electron scattering, gas phase, ab initio, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798, Crystallography, QD901-999

Abstract

X-ray and electron scattering from free gas-phase molecules is examined using the independent atom model (IAM) and ab initio electronic structure calculations. The IAM describes the effect of the molecular geometry on the scattering, but does not account for the redistribution of valence electrons due to, for instance, chemical bonding. By examining the total, i.e. energy-integrated, scattering from three molecules, fluoroform (CHF3), 1,3-cyclohexadiene (C6H8) and naphthalene (C10H8), the effect of electron redistribution is found to predominantly reside at small-to-medium values of the momentum transfer (q ≤ 8 Å−1) in the scattering signal, with a maximum percent difference contribution at 2 ≤ q ≤ 3 Å−1. A procedure to determine the molecular geometry from the large-q scattering is demonstrated, making it possible to more clearly identify the deviation of the scattering from the IAM approximation at small and intermediate q and to provide a measure of the effect of valence electronic structure on the scattering signal.

Published

2024

28. Unveiling ductile, rare-earth-free structural materials: A DFT exploration of MnTi and MnZr.

Author

Benaissa, Mohammed, Bouchaour, Mama, Merad, Laarej, Maloufi, Nabila, Abdelkader, Hayet Si, Bayram, Mustafa, Ghani, Ruqayyah Haider, Alhassan, Muataz S., and Menni, Younes

Abstract

This paper presents a theoretical exploration of the electronic, structural, and mechanical attributes inherent in three rare-earth-free intermetallic compounds, namely, MnTi, MnZr, and MnHf. Employing density functional theory (DFT) calculations with the Implementation of projector augmented wave (PAW); our investigation adopts the supercell approach to meticulously determine the structural and mechanical properties of these materials. The findings reveal that MnTi and MnZr exhibit intrinsic ductility, positioning them as viable contenders for applications demanding high-strength structures. In contrast, MnHf demonstrates mechanical instability. This study provides promising insights into the mechanical characteristics of MnTi and MnZr, underscoring their potential as sustainable structural materials, given the abundance and non-toxic nature of their constituents. The research findings presented herein contribute to the understanding of rare-earth-free intermetallics, offering valuable information for applications in materials science and engineering. [ABSTRACT FROM AUTHOR]

Published

2024

29. Discovery of Stable Surfaces with Extreme Work Functions by High‐Throughput Density Functional Theory and Machine Learning.

Author

Schindler, Peter, Antoniuk, Evan R., Cheon, Gowoon, Zhu, Yanbing, and Reed, Evan J.

Subjects

*DENSITY functional theory, *MACHINE theory, *MACHINE learning, *ELECTRON emission, *ENERGY conversion

Abstract

The work function is the key surface property that determines the energy required to extract an electron from the surface of a material. This property is crucial for thermionic energy conversion, band alignment in heterostructures, and electron emission devices. This work presents a high‐throughput workflow using density functional theory (DFT) to calculate the work function and cleavage energy of 33,631 slabs (58,332 work functions) that are created from 3,716 bulk materials. The number of calculated surface properties surpasses the previously largest database by a factor of ≈27. Several surfaces with an ultra‐low (<2 eV) and ultra‐high (>7 eV) work function are identified. Specifically, the (100)‐Ba‐O surface of BaMoO3 and the (001)‐F surface of Ag2F have record‐low (1.25 eV) and record‐high (9.06 eV) steady‐state work functions. Based on this database a physics‐based approach to featurize surfaces is utilized to predict the work function. The random forest model achieves a test mean absolute error (MAE) of 0.09 eV, comparable to the accuracy of DFT. This surrogate model enables rapid predictions of the work function (≈ 105 faster than DFT) across a vast chemical space and facilitates the discovery of material surfaces with extreme work functions for energy conversion and electronic device applications. [ABSTRACT FROM AUTHOR]

Published

2024

30. Potential energy surface and quantum dynamics calculation of SH2− (2A′) based on ab initio scaled external correlation correction.

Author

Ma, Hongyu and Gu, Ning

Subjects

*POTENTIAL energy surfaces, *QUANTUM theory, *SURFACE dynamics, *GROUND state energy, *WAVE packets

Abstract

An accurate interatomic potential energy surface for ground state of SH2− is reported at the multireference configuration interaction level of theory using aug–cc–pVQZ basis set. The calculated ab initio energy points are utilized, after semi-empirically correcting the dynamical correlation by the many-body expansion-scaled external correlation method. To verify the accuracy of the potential energy surface, molecular reaction dynamics, including the relationship between reaction probability and collision energy, thermal rate constant, and integral scattering cross section are calculated by using the quantum time-dependent wave packet method. The final results show that our potential energy surface is accurate and the molecular reaction dynamics results are satisfactory, and the accurate potential energy surface and its dynamics results can also lay a foundation for the future experimental research of SH−-containing molecules. This study provides a reasonable ionic chemical dissociation channel for the dynamics, A global many-body expansion (MEB) PES is reported by fitting high-precision ab initio energies calculated at the multireference configuration interaction level with Davidson correction (MRCI(Q)) and the aug-cc-pVQZ basis set (AVQZ). By comparing with the integral cross section with experimental result, which have agreement with the previous experimental and theoretical values. Our theoretical results can provide effective support for future dynamic experiments. [ABSTRACT FROM AUTHOR]

Published

2024

31. An Ab Initio Study of the Effect of Hydration on the Vibrational Spectrum of Hydrogen Vanadate Ion.

Author

Pye, Cory C., Berryman, Victoria E. J., and Goodall, Barbara L.

Subjects

*VIBRATIONAL spectra, *HYDROGEN ions, *HYDRATION, *ISOMERS, *RAMAN spectroscopy

Abstract

The geometries, energies, and vibrational frequencies of various isomers of HVO42−(H2O)n, n = 0–6 are calculated at various levels up to MP2/6−31 + G*. These properties are studied as a function of increasing cluster size. The calculations predict the vibrational frequencies, the full-widths at half-height, and a strong temperature and solvent dependence of the V–O(H) stretching and VOH bending vibration. [ABSTRACT FROM AUTHOR]

Published

2024

32. Term energies and radiative atomic data of carbon-like ions Na VI and Al VIII.

Author

Sun, Yan, Hu, Feng, Chen, Qing, Chen, Yunlong, Liu, Dongdong, Chen, Xuanshi, Shi, Zhe, Liu, Xi, Liu, Yan, Du, Wenyuan, and Sang, Cuicui

Abstract

Excitation energies belonging to the (1s2)2s22p2, 2s22p3p, 2s2p3, 2s22p3s, and 2s22p3d configurations of carbon-like Na VI and Al VIII have been calculated with the multi-configuration Rayleigh–Ritz variation method and restricted variation method, as well as wavelengths, line strengths, oscillator strengths, transition rates for electric dipole transitions among these terms. High-accuracy calculations have been performed using a moderate scale of Slater basis function and accurate treatments of relativity, electron correlation, and quantum electrodynamic (QED) effects. The line strengths, transition oscillator strengths, and transition probabilities for the electric dipole transitions are determined. Deviations of line strengths between the length and velocity gauges are discussed, as well as with the experimentally compiled values from the National Institute for Standards and Technology (NIST) and other theoretical data wherever available. Furthermore, the accuracy of each electric dipole transition is assessed. The present results are accurate enough for identification of emission lines involving these terms and are also useful for precise spectral modeling and diagnosing in astrophysical and laboratory plasmas. [ABSTRACT FROM AUTHOR]

Published

2024

33. Anti‐Coronavirus Activity of Certain Herbacetin Derivatives, A Theoretical Study.

Author

Rafiee, Marjan A.

Subjects

*NATURAL orbitals, *AB-initio calculations, *COUPLING constants, *AMINO group, *HYDROXYL group

Abstract

Flavonoids are natural products commonly found in the human diet with anti‐viral activity. The electrochemical activity of flavonoids is effective in their inhibitory properties. Herbacetin is an anti‐coronavirus drug from the flavonoid family. To understand structure‐electrochemical activity relations, ab initio calculations on some selected herbacetin derivatives were carried out using Gaussian 09 in B3LYP/6‐311G*. The effect of the position and type of the various substituents in the ring A of the flavone backbone are considered. The oxygen charge density of the hydroxyl group on C8 (O8) in the considered herbacetins was compared using nuclear quadrupole coupling constants (NQCC) calculations. Results showed that the presence of the amino group in the ortho position of O8 has the most significant effect on increasing the charge density of the O8 atom (O8‐NQCC=9.23 MHz). Based on the proposed mechanism of these drugs, ortho‐amino herbacetin is expected to show a significant anti‐coronavirus effect. Comparison of calculated O8‐NQCCs of tangeretin and nobiletin with herbacetin shows that with the replacement of OH with OCH3, the charge density of oxygen atoms decreases (about 2 MHz). Therefore tangeretin and nobiletin have a lower drug effect than herbacetin. Natural bond orbital (NBO) results are in agreement with calculated NQCCs. [ABSTRACT FROM AUTHOR]

Published

2024

34. Improved Approach for ab Initio Calculations of Rate Coefficients for Secondary Reactions in Acrylate Free-Radical Polymerization.

Author

Lugo, Fernando A., Edeleva, Mariya, Van Steenberge, Paul H. M., and Sabbe, Maarten K.

Subjects

*AB-initio calculations, *ADDITION polymerization, *COMPUTATIONAL chemistry, *POLYMERS, *POLYMERIZATION, *MONTE Carlo method, *POLYMER structure

Abstract

Secondary reactions in radical polymerization pose a challenge when creating kinetic models for predicting polymer structures. Despite the high impact of these reactions in the polymer structure, their effects are difficult to isolate and measure to produce kinetic data. To this end, we used solvation-corrected M06-2X/6-311+G(d,p) ab initio calculations to predict a complete and consistent data set of intrinsic rate coefficients of the secondary reactions in acrylate radical polymerization, including backbiting, β-scission, radical migration, macromonomer propagation, mid-chain radical propagation, chain transfer to monomer and chain transfer to polymer. Two new approaches towards computationally predicting rate coefficients for secondary reactions are proposed: (i) explicit accounting for all possible enantiomers for reactions involving optically active centers; (ii) imposing reduced flexibility if the reaction center is in the middle of the polymer chain. The accuracy and reliability of the ab initio predictions were benchmarked against experimental data via kinetic Monte Carlo simulations under three sufficiently different experimental conditions: a high-frequency modulated polymerization process in the transient regime, a low-frequency modulated process in the sliding regime at both low and high temperatures and a degradation process in the absence of free monomers. The complete and consistent ab initio data set compiled in this work predicts a good agreement when benchmarked via kMC simulations against experimental data, which is a technique never used before for computational chemistry. The simulation results show that these two newly proposed approaches are promising for bridging the gap between experimental and computational chemistry methods in polymer reaction engineering. [ABSTRACT FROM AUTHOR]

Published

2024

35. The heavy Carbene analogues SbH2+ and BiH2+. Convergent quantum mechanical studies*.

Author

Jin, Jincan, Mull, Henry F., Turney, Justin M., and Schaefer III, Henry F.

Subjects

*HEAT of reaction, *GROUND state energy, *BISMUTH

Abstract

In 2021 Olaru, Mebs, and Beckmann reported the synthesis of remarkable cationic carbene analogues $ \mathrm{PR_2^+} $ P R 2 + and $ \mathrm{AsR_2^+} $ As R 2 + . This work followed the same group's synthesis of $ \mathrm{SbR_2^+} $ Sb R 2 + and $ \mathrm{BiR_2^+} $ Bi R 2 + . To better understand these important systems, $ \mathrm{SbH_2^+} $ Sb H 2 + and $ \mathrm{BiH_2^+} $ Bi H 2 + have been studied with high level ab initio quantum mechanical methods. Geometries were optimised with the CCSDT(Q) method with the cc-pwCVTZ-PP basis set using small core pseudopotentials. Fundamental vibrational frequencies were computed to provide theoretical predictions for future synthetic studies. Relative energies with respect to $ \mathrm{Pn^+} $ P n + + $ \mathrm{H_2} $ H 2 ( $ \mathrm{Pn} $ Pn = $ \mathrm{Sb} $ Sb , $ \mathrm{Bi} $ Bi ) were determined at the CCSDT/CBS level of theory via the Focal Point Analysis method, and anharmonic zero-point vibrational energy and higher order contributions were also computed. For $ \mathrm{SbH_2^+} $ Sb H 2 + , we obtained R = 1.697 Å and $ \theta =90.8^{\circ } $ θ = 90.8 ∘ with $ \mathrm{Sb^+ + H_2 \rightarrow SbH_2^+} $ S b + + H 2 → Sb H 2 + reaction enthalpy of $ \Delta H = -18.71\,{\rm kcal}\ {\rm mol}^{-1} $ ΔH = − 18.71 kcal mol − 1 . For $ \mathrm{BiH_2^+} $ Bi H 2 + , the analogous results were R = 1.774 Å, $ \theta =89.7^{\circ } $ θ = 89.7 ∘ , and $ \Delta H = -7.64\,{\rm kcal}\,{\rm mol}^{-1} $ ΔH = − 7.64 kcal mol − 1 for $ \mathrm{Bi^+ + H_2 \rightarrow BiH_2^+} $ B i + + H 2 → Bi H 2 + . [ABSTRACT FROM AUTHOR]

Published

2024

36. Exciton Ground State Fine Structure and Excited States Landscape in Layered Halide Perovskites from Combined BSE Simulations and Symmetry Analysis.

Author

Quarti, Claudio, Giorgi, Giacomo, Katan, Claudine, Even, Jacky, and Palummo, Maurizia

Subjects

*BETHE-Salpeter equation, *SPIN-orbit interactions, *PEROVSKITE, *HALIDES, *ENERGY conversion, *ORGANIC dyes

Abstract

Layered halide perovskites are solution‐processed natural heterostructures where quantum and dielectric confinement down to the nanoscale strongly influence the optical properties, leading to stabilization of bound excitons. Detailed understanding of the exciton properties is crucial to boost the exploitation of these materials in energy conversion and light emission applications, with on‐going debate related to the energy order of the four components of the most stable exciton. To provide theoretical feedback and solve among contrasting literature reports, this work performs ab initio solution of the Bethe–Salpeter equation (BSE) for symmetrized reference Cs2PbX4 (X = I and Br) models, with detailed interpretation of the spectroscopic observables based on group‐theory analysis. Simulations predict the following Edark < Ein‐plane < Eout‐of‐plane fine‐structure assignment, consistent with recent magneto‐absorption experiments and obtain similar increase in dark/bright splitting when going from lead‐iodide to a lead‐bromide composition as found experimentally. The authors further suggest that polar distortions may lead to stabilization of the in‐plane component and end‐up in a bright lowest exciton component, discuss exciton landscape over a broad energy range and clarify the exciton spin‐character, when large spin‐orbit coupling is in play, to rationalize the potential of halide perovskites as triplet sensitizers in combination with organic dyes. [ABSTRACT FROM AUTHOR]

Published

2024

37. Ab initio studies of counterion effects in molecular quantum‐dot cellular automata.

Author

Liza, Nishattasnim, Coe, Daniel J., Lu, Yuhui, and Blair, Enrique P.

Subjects

*CELLULAR automata, *LOGIC circuits, *ELECTROSTATIC fields, *COGNITIVE computing, *CHARGE exchange, *QUANTUM dots

Abstract

Molecular quantum‐dot cellular automata (QCA) is a low‐power computing paradigm that may offer ultra‐high device densities and THz‐speed switching at room temperature. A single mixed‐valence (MV) molecule acts as an elementary QCA device known as a cell. Cells coupled locally via the electrostatic field form logic circuits. However, previously‐synthesized ionic MV molecular cells are affected by randomly‐located, nearby neutralizing counterions that can bias device states or change device characteristics, causing incorrect computational results. This ab initio study explores how non‐biasing counterions affect individual molecular cells. Additionally, we model two novel neutral, zwitterionic MV QCA molecules designed to avoid biasing and other undesirable counterionic effects. The location of the neutralizing counterion is controlled by integrating one counterion into each cell at a well‐defined, non‐biasing location. Each zwitterionic QCA candidate molecule presented here has a fixed, integrated counterion, which neutralizes the mobile charges used to encode the device state. [ABSTRACT FROM AUTHOR]

Published

2024

38. Extracting the electronic structure signal from X-ray and electron scattering in the gas phase.

Author

Northey, Thomas, Kirrander, Adam, and Weber, Peter M.

Subjects

*ELECTRON gas, *X-ray scattering, *ELECTRONIC structure, *ATOMIC models, *ELECTRON scattering, *MOMENTUM transfer

Abstract

X-ray and electron scattering from free gas-phase molecules is examined using the independent atom model (IAM) and ab initio electronic structure calculations. The IAM describes the effect of the molecular geometry on the scattering, but does not account for the redistribution of valence electrons due to, for instance, chemical bonding. By examining the total, i.e. energy-integrated, scattering from three molecules, fluoroform (CHF3), 1,3-cyclohexadiene (C6H8) and naphthalene (C10H8), the effect of electron redistribution is found to predominantly reside at small-to-medium values of the momentum transfer (q ≤ 8 Å-1) in the scattering signal, with a maximum percent difference contribution at 2 ≤ q ≤ 3 Å-1. A procedure to determine the molecular geometry from the large-q scattering is demonstrated, making it possible to more clearly identify the deviation of the scattering from the IAM approximation at small and intermediate q and to provide a measure of the effect of valence electronic structure on the scattering signal. [ABSTRACT FROM AUTHOR]

Published

2024

39. Triboelectric Charging Properties of the Functional Groups of Common Pharmaceutical Materials Using Density Functional Theory Calculations.

Author

Middleton, James R., Ghadiri, Mojtaba, and Scott, Andrew J.

Subjects

*TRIBOELECTRICITY, *DENSITY functional theory, *CHARGE transfer, *FUNCTIONAL groups, *ELECTROSTATIC discharges, *FRONTIER orbitals, *ELECTRIC charge

Abstract

Triboelectrification is a ubiquitous and poorly understood phenomenon in powder processing, particularly for pharmaceutical powders. Charged particles can adhere to vessel walls, causing sheeting; they can also cause agglomeration, threatening the stability of powder formulations, and in extreme cases electrostatic discharges, which present a serious fire and explosion hazard. Triboelectrification is highly sensitive to environmental and material conditions, which makes it very difficult to compare experimental results from different publications. In this work, density functional theory (DFT) is used to investigate the charge transfer characteristics of several functional groups of paracetamol in order to better understand the mechanisms of charging at the nanoscale and the influence of the environmental and material properties on charge transfer. This is achieved by studying the structure and electronic properties at the molecule–substrate interface. Using this molecule–substrate approach, the charging contributions of individual functional groups are explored by examining the Hirschfeld charges, the charge density difference between the molecule and substrate, the density of states, and the location of the frontier orbitals (HOMO and LUMO) of a paracetamol molecule. Charge density difference calculations indicate a significant transfer of charge from the molecule to the surface. Observable regions of electron density enrichment and depletion are evident around the electron-donating and -withdrawing groups, respectively. The density of states for the paracetamol molecule evolves as it approaches the surface, and the band gap disappears upon contact with the substrate. Hirshfeld charge analysis reveals asymmetry in the charge redistribution around the molecule, highlighting the varying charging tendencies of different atoms. [ABSTRACT FROM AUTHOR]

Published

2024

40. A theoretical study on excited-state dynamical properties and laser cooling of zinc monohydride including spin-orbit couplings

Author

Donghui Li, Faiza Fayyaz, and Wensheng Bian

Subjects

electronic state crossing, vibrational branching ratio, ultracold molecule, ab initio, spin-orbit coupling, Chemistry, QD1-999

Abstract

By means of highly accurate ab initio and dynamical calculations, we identify a suitable laser cooling candidate that contains a transition metal element, namely zinc monohydride (ZnH). The internally contracted multireference configuration interaction method is employed to compute the five lowest-lying Λ-S states of ZnH with the spin-orbit coupling effects included, and very good agreement is obtained between our calculated and experimental spectroscopic data. Our findings show that the position of crossing point of the A2Π and B2Σ+ states of ZnH is above the v′ = 2 vibrational level of the A2Π state indicating that the crossings with higher electronic states will have no effect on laser cooling. Hence, we construct a feasible laser-cooling scheme for ZnH using five lasers based on the A2Π1/2 → X2Σ+1/2 transition, which features a large vibrational branching ratio R00 (0.8458), a large number of scattered photons (9.8 × 103) and an extremely short radiative lifetime (64 ns). The present work demonstrates the importance of electronic state crossings and spin-orbit couplings in the study of molecular laser cooling.

Published

2024

41. Co-designing ab initio electronic structure methods on a RISC-V vector architecture [version 1; peer review: 3 approved]

Author

Rogeli Grima Torres, Pablo Vizcaíno, José Julio Gutiérrez Moreno, and Filippo Mantovani

Subjects

High-performance computing, co-design, ab initio, RISC-V, materials science, eigensolver library, eng, Science, Social Sciences

Abstract

Ab initio electronic structure applications are among the most widely used in High-Performance Computing (HPC), and the eigenvalue problem is often their main computational bottleneck. This article presents our initial efforts in porting these codes to a RISC-V prototype platform leveraging a wide Vector Processing Unit (VPU). Our software tester is based on a mini-app extracted from the ELPA eigensolver library. The user-space Vehave and a RISC-V vector architecture implemented on an FPGA were tested. Metrics from both systems and different vectorisation strategies were extracted, ranging from the most simple and portable one (using autovectorisation and assisting this by fusing loops in the code) to the more complex one (using intrinsics). We observed a progressive reduction in the number of vectorial instructions, executed instructions and computing cycles with the different methodologies, which will lead to a substantial speed-up in the calculations. The obtained outcomes are crucial in advancing the porting of computational materials and molecular science codes to (post)-exascale architectures using RISC-V-based technologies fully developed within the EU. Our evaluation also provides valuable feedback for hardware designers, engineers and compiler developers, making this use case pivotal for co-design efforts.

Published

2024

42. Magnetocaloric effect, magnetothermal and elastic properties of SmFe3 and ErFe3 compounds

Author

Mohammad, Fatema Z., Abdel-Kader, Ahmed, Hammad, Tarek, Yehia, Sherif, Aly, Samy H., and Abu-Elmagd, Mohammed Said Mohammed

Published

2024

43. Structural, Mechanical, Elastic, Electronic, Magnetic and Optical Properties of Spinel Compounds ATi2S4 (A=Ca, Sr and Ba): AB Initio Study

Author

Bousahla Mohammed Nadir, Bousahla Mohammed Alaa, Chahed Abbes, Bousahla Zouaoui, Rozale Habib, and Bendjilali Hadjer

Subjects

ab initio, dft, spinels, structural, elastic, optical, Physics, QC1-999

Abstract

This research explored the crystal structure, mechanical and elastic, electronic, magnetic, and optical properties of spinel compoundsATi2S4 (A=Ca, Sr and Ba). The ferromagnetic phase of the compounds was found to be stable, and FP-LAPW method within density functional theory (DFT) was used to calculate and compare the lattice constant a, bulk modulus B0, and its pressure derivative B'. The exchange-correlation potential was also treated with both the GGA and TB-mBJ potential approximation. The results of the study showed that the examined spinels exhibit half-metallic behavior, which makes them a potential material for use in spintronic and optoelectronic devices.

Published

2023

44. Exploring Unconventional Electron Distribution Patterns: Contrasts Between FeSe and FeSe/STO Using an Ab Initio Approach

Author

Chi-Ho Wong and Rolf Lortz

Subjects

ab initio, antiferromagnetic phonon, spin-density wave, charge-density wave, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

For more than a decade, the unusual distribution of electrons observed in ARPES (angle-resolved photoemission spectroscopy) data within the energy range of ~30 meV to ~300 meV below the Fermi level, known as the ARPES energy range, has remained a puzzle in the field of iron-based superconductivity. As the electron–phonon coupling of FeSe/SrTiO3 is very strong, our investigation is centered on exploring the synergistic interplay between spin-density waves (SDW) and charge-density waves (CDW) with differential phonons at the interface between antiferromagnetic maxima and minima under wave interference. Our analysis reveals that the synergistic energy is proportional to the ARPES energy range, as seen in the comparison between FeSe and FeSe/SrTiO3. This finding may suggest that the instantaneous interplay between these intricate phenomena may play a role in triggering the observed energy range in ARPES.

Published

2024

45. Equilibrium Structures of Propane and 2,2-Difluoropropane and Comparison with Other Two-Top Molecules

Author

Jean Demaison, Natalja Vogt, and Agnès Perrin

Subjects

equilibrium structure, semiexperimental, ab initio, propane, Organic chemistry, QD241-441

Abstract

The Born–Oppenheimer ab initio equilibrium structures of propane (CH3)2CH2 and 2,2-difluoropropane (CH3)2CF2 were computed at the CCSD(T) level of theory using a basis set of quadruple zeta quality. The semiexperimental structure of propane was also determined from the ground state rotational constants corrected for rovibrational corrections calculated at the MP2 level of theory. Structural comparisons are made with other molecules and are discussed in terms of the quantum theory of atoms in molecules.

Published

2024

46. Serine protease inhibitor 3 (Serpin3) from Penaeus vannamei selectively interacts with Vibrio parahaemolyticusPirAvp.

Author

Le, Thanh‐Nguyen, Dinh, Thuan‐Thien, Mai‐Hoang, Thuy‐Dung, Razzazi‐Fazeli, Ebrahim, and Tran‐Van, Hieu

Abstract

Acute Hepatopancreatic Necrosis Disease (AHPND) represents a significant challenge in the field of shrimp aquaculture. This disease is primarily caused by Vibrio parahaemolyticus strains harbouring the pVA1 plasmid encoding the PirAvp and PirBvp toxins. To combat this epidemic and mitigate its devastating consequences, it is crucial to identify and characterize the receptors responsible for the binding of these pathogenic toxins. Our studied discovered that Penaeus vannamei's Serine protease inhibitor 3 (PvSerpin3) derived from shrimp hepatopancreatic tissues could bind to recombinant PirAvp, confirming its role as a novel PirAvp‐binding protein (PABP). Through comprehensive computational methods, we revealed two truncated PirAvp–binding proteins derived from PvSerpin3 called Serpin3(13) and Serpin3(22), which had higher affinity to PirAvp than the full‐length PvSerpin3. The PABP genes were amplified from a cDNA library that was reversed from total RNA extracted from shrimp, cloned and expressed in Escherichia coli. Three PABP inclusion bodies were refolded to obtain the soluble form, and the recovery efficacy was found to be 100% for Serpin3 and Serpin3(13), while Serpin3(22) had a recovery efficacy of roundly 50%. Co‐Immunoprecipitation (co‐IP) and dot blot assays substantiated the interaction of these recombinant PABPs with both recombinant PirAvp and VPAHPND (XN89)‐producing natural toxins. [ABSTRACT FROM AUTHOR]

Published

2024

47. Ab Initio Density Functional Theory Calculation: Americium Hydrolysis Mechanism.

Author

Shan, Na and Gao, Tao

Subjects

*DENSITY functional theory, *ORBITAL hybridization, *AMERICIUM, *ELECTROSTATIC interaction, *EXOTHERMIC reactions

Abstract

The hydrolysis mechanism of americium was calculated using density functional theory, and the detailed microscopic reaction mechanism was obtained. The results show that americium reacts with water along the octet state to produce oxides and H2, and that this reaction is exothermic. The interaction between Am and O atoms gradually changes from initially electrostatic interaction to covalent interaction, and continues to strengthen. During the reaction process, Am atoms always lose electrons, the 5f orbital is obviously involved, and there is df orbital hybridization. This study provides the necessary theoretical data support for the theoretical and experimental study of the actinide system. [ABSTRACT FROM AUTHOR]

Published

2024

48. Ab initio study of defect interactions between the negatively charged nitrogen vacancy centre and the carbon self-interstitial in diamond.

Author

Kirkpatrick, Andrew R., Chen, Guangzhao, Witkowska, Helen, Brixey, James, Green, Ben L., Booth, Martin J., Salter, Patrick S., and Smith, Jason M.

Subjects

*DIAMONDS, *NANODIAMONDS, *DENSITY functional theory, *CARBON

Abstract

Fabrication techniques for nitrogen-vacancy centres in diamond require the creation of Frenkel defects (vacancy-interstitial pairs) the components of which can interact with formed NV centres affecting their photophysical properties. Here we use Density Functional Theory simulations of inter-defect electronic and strain interactions to explore how the NV centre and carbon self-interstitial interact in different configurations. We find that hybridization occurs between the NV centre e-orbitals and the carbon self-interstitial when an interstitial is present on the vacancy side of the NV centre. We propose that this phenomenon may explain the fluorescence blinking of NV centres observed during annealing. This article is part of the Theo Murphy meeting issue 'Diamond for quantum applications'. [ABSTRACT FROM AUTHOR]

Published

2024

49. Accurate ab initio potential energy surface, rovibrational energy levels and resonance interactions of triplet (X~3B1) methylene.

Author

Egorov, Oleg, Rey, Michaël, Viglaska, Dominika, and Nikitin, Andrei V.

Subjects

*POTENTIAL energy surfaces, *DELOCALIZATION energy, *GROUND state energy, *QUANTUM numbers, *QUALITY factor

Abstract

In this work, we report rovibrational energy levels for four isotopologues of methylene (CH2, CHD, CD2, and 13CH2) in their ground triplet electronic state (X~3B1) from variational calculation up to ~10,000 cm−1 and using a new accurate ab initio potential energy surface (PES). Triplet methylene exhibits a large‐amplitude bending vibration and can reach a quasilinear configuration due to its low barrier (~2000 cm−1). To construct the ab initio PES, the Dunning's augmented correlation‐consistent core‐valence orbital basis sets were employed up to the sextuple‐ζ quality [aug‐cc‐pCVXZ, X = T, Q, 5, and 6] combined with the single‐ and double‐excitation unrestricted coupled cluster approach with a perturbative treatment of triple excitations [RHF‐UCCSD(T)]. We have shown that the accuracy of the ab initio energies is further improved by including the corrections due to the scalar relativistic effects, DBOC and high‐order electronic correlations. For the first time, all the available experimental rovibrational transitions were reproduced with errors less than 0.12 cm−1, without any empirical corrections. Unlike more "traditional" nonlinear triatomic molecules, we have shown that even the energies of the ground vibrational state (000) with rather small rotational quantum numbers are strongly affected by the very pronounced rovibrational resonance interactions. Accordingly, the polyad structure of the vibrational levels of CH2 and CD2 was analyzed and discussed. The comparison between the energy levels obtained from the effective Watson A‐reduced Hamiltonian, from the generating‐function approach and from a variational calculation was given. [ABSTRACT FROM AUTHOR]

Published

2024

50. Extending first principles spectroscopy to disordered materials : a study on amorphous and crystalline aluminas

Author

Harper, Angela F., Morris, Andrew J., and Payne, Michael

Subjects

ab initio, ab initio molecular dynamics, AIMD, alumina, amorphous, density functional theory, DFT, first principles, NMR, nuclear magnetic resonance, solid state

Abstract

Advancing the next generation of materials for solid-state devices requires an understanding of their underlying electronic structure; yet the disordered nature of many materials hinders progress in creating an atomic-level model. Although X-ray diffraction (XRD) is used to match crystalline models with experiment, XRD fails to characterize amorphous structures due to their lack of periodicity. However, nuclear magnetic resonance (NMR) and X-ray absorption spectroscopy (XAS) are two locally sensitive techniques that do not rely on periodicity. To compare amorphous models to experiment, it is then necessary to extend first principles calculations of NMR and XAS to amorphous materials. In this thesis, I apply first principles methods for calculating NMR and XAS spectra, to both crystalline and amorphous phases of alumina (Al₂O₃). First, I analyze the Al K-edge XAS for crystalline α- and γ-Al₂O₃ at finite temperature. Phase transitions from Al s to mixed s-p states are symmetry forbidden at 0 K, but incorporating the effects of temperature reproduces these transitions. Applying this method to γ-Al₂O₃ reproduces a peak at 1568 eV in the XAS which is not observed in the first principles calculations at 0 K. I then address the question of how to calculate these spectra for an amorphous phase. By using representative configurations of am-Al₂O₃ from ab initio molecular dynamics (AIMD), I calculate averaged NMR and XAS spectra for am-Al₂O₃. I show that both the experimental ²⁷Al isotropic chemical shifts and quadrupolar lineshapes are successfully reproduced using this method. Further, by calculating XAS spectra for each individual Al atom in this model, I am able to deconvolute the experimental XAS into site-specific spectra from four-, five-, and six-fold coordinated Al. Finally, I examine how the structure of am-Al₂O₃ is affected by hydrogen fluoride incorporation in Li-ion batteries, by calculating ²⁷Al NMR on protonated and fluorinated amorphous aluminas. These results are in line with experimental ²⁷Al NMR evidence for a pathway of HF attack involving the formation of AlO(6−x)Fx species during battery cycling.

Published

2022