Quantum ESPRESSO toward the exascale

Quantum ESPRESSO is an open-source distribution of computer codes for quantum-mechanical materials modeling, based on density-functional theory, pseudopotentials, and plane waves, and renowned for its performance on a wide range of hardware architectures, from laptops to massively parallel computers, as well as for the breadth of its applications. In this paper, we present a motivation and brief review of the ongoing effort to port Quantum ESPRESSO onto heterogeneous architectures based on hardware accelerators, which will overcome the energy constraints that are currently hindering the way toward exascale computing

Advanced capabilities for materials modelling with Quantum ESPRESSO

Quantum ESPRESSO is an integrated suite of open-source computer codes for quantum simulations of materials using state-of-the art electronic-structure techniques, based on density-functional theory, density-functional perturbation theory, and many-body perturbation theory, within the plane-wave pseudo-potential and projector-augmented-wave approaches. Quantum ESPRESSO owes its popularity to the wide variety of properties and processes it allows to simulate, to its performance on an increasingly broad array of hardware architectures, and to a community of researchers that rely on its capabilities as a core open-source development platform to implement theirs ideas. In this paper we describe recent extensions and improvements, covering new methodologies and property calculators, improved parallelization, code modularization, and extended interoperability both within the distribution and with external software

Fully ab initio IR spectra for complex molecular systems from perturbative vibrational approaches: Glycine as a test case

Perturbative anharmonic computations have been used to simulate the IR spectrum of glycine, taking into account its three most stable conformers. The theoretical results have been directly compared with their experimental counterparts, showing good agreement between the latter and the spectra obtained after proper averaging of the contributions from the three most stable glycine conformers. The results show that direct simulation of the overall vibrational spectrum within a second-order perturbative treatment is feasible and leads to a better understanding of experimental data. Additionally, it has been shown that accurate results can be obtained even when several molecular species need to be considered simultaneously. The computations performed at the B3LYP/aug-N07D level have shown their reliability in the prediction of both vibrational energy levels and IR intensities beyond the harmonic approximation. This kind of computations represents an important tool for the analysis of vibrational spectra for complex medium-to-large molecular systems. (C) 2011 Elsevier B.V. All rights reserved

Guía de estudio para ser usada como complemento de la unidad audiotutorial sobre el mismo tema

The recent implementation of the computation of infrared (IR) intensities beyond the double-harmonic approximation [J. Bloino and V. Barone, J. Chem. Phys. 136, 124108 (2012)] paved the route to routine calculations of infrared spectra for a wide set of molecular systems. Halogenated organic compounds represent an interesting class of molecules, from both an atmospheric and computational point of view, due to the peculiar chemical features related to the halogen atoms. In this work, we simulate the IR spectra of eight halogenated molecules (CH2F2, CHBrF2, CH2DBr, CF3Br, CH2CHF, CF2CFCl, cis-CHFCHBr, cis-CHFCHI), using two common hybrid and double-hybrid density functionals in conjunction with both double- and triple-zeta quality basis sets (SNSD and cc-pVTZ) as well as employing the coupled-cluster theory with basis sets of at least triple-zeta quality. Finally, we compare our results with available experimental spectra, with the aim of checking the accuracy and the performances of the computational approaches. (C) 2013 AIP Publishing LLC