Prediction And Calculation Of Crystal Structures

Prediction and Calculation of Crystal Structures

Author : Sule Atahan-Evrenk

Publisher : Springer

Page : 299 pages

File Size : 21,31 MB

Release : 2014-05-06

Category : Science

ISBN : 331905774X

Get eBook

Book Description

The series Topics in Current Chemistry presents critical reviews of the present and future trends in modern chemical research. The scope of coverage is all areas of chemical science including the interfaces with related disciplines such as biology, medicine and materials science. The goal of each thematic volume is to give the non-specialist reader, whether in academia or industry, a comprehensive insight into an area where new research is emerging which is of interest to a larger scientific audience. Each review within the volume critically surveys one aspect of that topic and places it within the context of the volume as a whole. The most significant developments of the last 5 to 10 years are presented using selected examples to illustrate the principles discussed. The coverage is not intended to be an exhaustive summary of the field or include large quantities of data, but should rather be conceptual, concentrating on the methodological thinking that will allow the non-specialist reader to understand the information presented. Contributions also offer an outlook on potential future developments in the field. Review articles for the individual volumes are invited by the volume editors. Readership: research chemists at universities or in industry, graduate students.



First-Principles Prediction of Structures and Properties in Crystals

Author : Dominik Kurzydlowsk

Publisher : MDPI

Page : 128 pages

File Size : 12,36 MB

Release : 2019-10-25

Category : Science

ISBN : 3039216708

Get eBook

Book Description

The term “first-principles calculations” is a synonym for the numerical determination of the electronic structure of atoms, molecules, clusters, or materials from ‘first principles’, i.e., without any approximations to the underlying quantum-mechanical equations. Although numerous approximate approaches have been developed for small molecular systems since the late 1920s, it was not until the advent of the density functional theory (DFT) in the 1960s that accurate “first-principles” calculations could be conducted for crystalline materials. The rapid development of this method over the past two decades allowed it to evolve from an explanatory to a truly predictive tool. Yet, challenges remain: complex chemical compositions, variable external conditions (such as pressure), defects, or properties that rely on collective excitations—all represent computational and/or methodological bottlenecks. This Special Issue comprises a collection of papers that use DFT to tackle some of these challenges and thus highlight what can (and cannot yet) be achieved using first-principles calculations of crystals.



Methods and Applications of Crystal Structure Prediction

Author : Royal Society of Chemistry

Publisher : Faraday Discussions

Page : 668 pages

File Size : 14,76 MB

Release : 2018

Category : Crystal growth

ISBN : 9781788011709

Get eBook

Book Description

This volume gathers key researchers representing the full scientific scope of the crystal structure prediction.



Methods and Applications of Crystal Structure Prediction

Author :

Publisher :

Page : 666 pages

File Size : 14,54 MB

Release : 2018

Category : Crystallography

ISBN :

Get eBook

Book Description

The prediction of crystal structures from first principles has been one of the grand challenges for computational methods in chemistry and materials science. The goal of being able to reliably predict crystal structures at an atomistic level of detail, given only the chemical composition as input, presents several challenges. A solution to the crystal structure prediction challenge requires advances in several areas of computational chemistry. This volume gathers key researchers representing the full scientific scope of the topic, including the developers of methods and software, those developing the application of the methods and interested experimentalists who may benefit from advances in predictive computational methods. This volume will appeal to researchers from computational chemistry, informatics, physics and materials science. Applications of crystal structure prediction methods also cover several fields, including crystallography, crystal engineering, mineralogy and pharmaceutical materials. The topics covered in this volume include: Structure searching methods ; Crystal structure evaluation: calculating relative stabilities and other criteria ; Applications of crystal structure prediction: organic molecular structures ; Applications of crystal structure prediction: inorganic and network structures.



Modern Methods of Crystal Structure Prediction

Author : Artem R. Oganov

Publisher : John Wiley & Sons

Page : 378 pages

File Size : 17,66 MB

Release : 2011-08-04

Category : Science

ISBN : 352764377X

Get eBook

Book Description

Gathering leading specialists in the field of structure prediction, this book provides a unique view of this complex and rapidly developing field, reflecting the numerous viewpoints of the different authors. A summary of the major achievements over the last few years and of the challenges still remaining makes this monograph very timely.



First-Principles Prediction of Structures and Properties in Crystals

Author : Dominik Kurzydlowski

Publisher :

Page : 1 pages

File Size : 31,52 MB

Release : 2019

Category : Electronic books

ISBN : 9783039216710

Get eBook

Book Description

The term "first-principles calculations" is a synonym for the numerical determination of the electronic structure of atoms, molecules, clusters, or materials from 'first principles', i.e., without any approximations to the underlying quantum-mechanical equations. Although numerous approximate approaches have been developed for small molecular systems since the late 1920s, it was not until the advent of the density functional theory (DFT) in the 1960s that accurate "first-principles" calculations could be conducted for crystalline materials. The rapid development of this method over the past two decades allowed it to evolve from an explanatory to a truly predictive tool. Yet, challenges remain: complex chemical compositions, variable external conditions (such as pressure), defects, or properties that rely on collective excitations-all represent computational and/or methodological bottlenecks. This Special Issue comprises a collection of papers that use DFT to tackle some of these challenges and thus highlight what can (and cannot yet) be achieved using first-principles calculations of crystals.



Polymorph Prediction of Organic (co-) Crystal Structures from a Thermodynamic Perspective

Author : Hin Chung Stephen Chan

Publisher :

Page : pages

File Size : 15,72 MB

Release : 2012

Category :

ISBN :

Get eBook

Book Description

A molecule can crystallise in more than one crystal structure, a common phenomenon in organic compounds known as polymorphism. Different polymorphic forms may have significantly different physical properties, and a reliable prediction would be beneficial to the pharmaceutical industry. However, crystal structure prediction (CSP) based on the knowledge of the chemical structure had long been considered impossible. Previous failures of some CSP attempts led to speculation that the thermodynamic calculations in CSP methodologies failed to predict the kinetically favoured structures. Similarly, regarding the stabilities of co-crystals relative to their pure components, the results from lattice energy calculations and full CSP studies were inconclusive. In this thesis, these problems are addressed using the state-of-the-art CSP methodology implemented in the GRACE software. Firstly, it is shown that the low-energy predicted structures of four organic molecules, which have previously been considered difficult for CSP, correspond to their experimental structures. The possible outcomes of crystallisation can be reliably predicted by sufficiently accurate thermodynamic calculations. Then, the polymorphism of 5- chloroaspirin is investigated theoretically. The order of polymorph stability is predicted correctly and the isostructural relationships between a number of predicted structures and the experimental structures of other aspirin derivatives are established. Regarding the stabilities of co-crystals, 99 out of 102 co-crystals and salts of nicotinamide, isonicotinamide and picolinamide reported in the Cambridge Structural Database (CSD) are found to be more stable than their corresponding co-formers. Finally, full CSP studies of two co-crystal systems are conducted to explain why the co-crystals are not easily obtained experimentally.



Computational Materials Discovery

Author : Artem Oganov

Publisher : Royal Society of Chemistry

Page : 470 pages

File Size : 39,8 MB

Release : 2018-10-30

Category : Science

ISBN : 1782629610

Get eBook

Book Description

A unique and timely book providing an overview of both the methodologies and applications of computational materials design.



The Crystalline States of Organic Compounds

Author : Angelo Gavezzotti

Publisher : Elsevier

Page : 304 pages

File Size : 37,24 MB

Release : 2021-11-25

Category : Science

ISBN : 0128237481

Get eBook

Book Description

The Crystalline States of Organic Compounds is a broad survey of the techniques by which molecular crystals are investigated, modeled, and applied, starting with the fundamentals of intra- and intermolecular bonding supplemented by a concise tutorial on present-day diffraction methods, then proceeding to an examination of crystallographic databases with their statistics and of such fundamental and fast-growing topics as intermolecular potentials, polymorphism, co-crystallization, and crystal structure prediction by computer. A substantial part of the book is devoted to the techniques of choice in modern simulation, Monte Carlo and molecular dynamics, with their most recent developments and application to formed crystals and to the concomitant phases involved in nucleation and growth. Drawing on the decades-long experience of its author in teaching and research in the field of organic solid state, The Crystalline States of Organic Compounds is an indispensable source of key insights and future directions for students and researchers at any level, in academia and in industry. Condenses theoretical information and practical methods in a single resource Provides a guide on the use of crystallographic databases, structure statistics, and molecular simulations Includes a large number of worked examples and tutorials, with extensive graphics and multimedia



Development and Applications of Composite and Low-Cost Approaches in Molecular Crystal Structure Prediction

Author : Luc LeBlanc

Publisher :

Page : 0 pages

File Size : 48,41 MB

Release : 2019

Category :

ISBN :

Get eBook

Book Description

Despite significant progress made in the last twenty years, the crystal structure prediction (CSP) of organic molecular solids remains challenging, as the demand to predict more complex crystal structures increases. On the one hand, relative energies between candidate crystal structures generated during a CSP protocol must be calculated accurately; on the other, the complexity of the crystal-energy landscape imposes stringent limitations on the method's computational cost. While plane-wave density-functional theory (DFT) methods have become the workhorse for the final stages of CSP protocols, due to their balance between high accuracy and efficiency, they remain prohibitively expensive during the early and intermediate stages. The primary aim of this thesis is the development of composite approaches for CSP, which comprise a geometry optimization using a low-cost method followed by a single- point energy calculation using plane-wave DFT with the exchange-hole dipole moment (XDM) dispersion model. The composite approaches were first tested on small molecular solids; assessment based on their abilities to produce absolute lattice energies was found to be misleading, and relative lattice energies provided a much better indicator of performance in a CSP context. To allow use of the XDM dispersion model with low-level methods, it was implemented in the SIESTA code, which uses numerical finite-support local orbitals to reduce the computational cost of the calculation. Composite approaches making use of the same DFT-D method both for low- and high-level DFT frameworks yielded the best ac- curacy, while remaining significantly cheaper than performing full geometry optimizations with plane-wave DFT. The composite approaches were then successfully employed for CSP of organic molecules with applications ranging from chiral organic semiconductors to pharmaceutical solids. Secondary objectives of this thesis sought to offer insight as to whether certain classes of solid-state materials are not appropriate benchmarks for method validation, and whether DFT-D methods are always suitable to describe all molecular crystals of interest. In particular, using compounds that form polytypes, e.g., crystalline aspirin, to validate com- putational methods was found to be inadvisable due to their high geometric and energetic similarity. Also, delocalization error, an often-overlooked limitation of most DFT methods, affected the correct identification of the protonation site in multicomponent acid-base crystals. This error greatly affects the reliability of these methods for validation of experi- mental (or the prediction of new) crystal structures. Overall, the work presented in this dissertation provides appropriate methodological and benchmarking tools to accelerate the intermediate stages of CSP protocols, while retaining high levels of accuracy and reliability in the crystal-energy landscapes generated, ultimately enabling the study of increasingly complex molecular crystals.