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Author: Vincent Jean Louis Dufour Publisher: ISBN: Category : Languages : en Pages :
Book Description
Hydrocarbon pyrolysis is a process that is thought to occur in the interior of icy giant planets. This reaction would transform the methane contained in the interior of these planets into diamond through compression to pressure of several tens of gigapascals and heating to temperatures of several thousands of kelvins. Even if it is commonly admitted that this reaction occurs, the conditions under which it takes place are still debated. Many experiments and theoretical calculations gave disagreeing predictions; some experiments led to the observation of diamond from hydrocarbon pyrolysis in pressure as low as 10 GPa and temperatures between 2,000 and 3,000 K, whereas other experiments and theoretical predictions claimed that diamond cannot be produced by hydrocarbon pyrolysis below 100 GPa. Several explanations have been proposed to explain these discrepancies; however, there is no consensus yet and one of the main reasons is that the precise mechanism of hydrocarbon pyrolysis is not precisely known. A crude mechanism is that methane separates into dihydrogen and carbon-rich molecules, such as large hydrocarbons or solids. Nevertheless, this simplified mechanism leaves many topics unstudied: first, the kinetic of the reaction remains unknown. This limitation implies that researchers cannot guarantee that their experiments or simulations were run for a sufficient time to reach equilibrium. Another poorly understood topic is the role of pressure and temperature; it is generally assumed that diamond is more likely to be synthesized when pressure and temperature increases. But the exact conditions in which diamond is produced and the role of pressure and temperature has not been studied yet. Finally, the role of the hydrogen content has not been investigated; Le Chatelier's principle implies that the less hydrogen in the system, the larger the hydrocarbons will be, but it is unknown which hydrogen content induces diamond production. Therefore, there is a need for a detailed mechanism of hydrocarbon pyrolysis. Discovering the hydrocarbon pyrolysis mechanism through experiments is impractical because of the extreme conditions undergone and the short time scales involved. Recently, the rise of reactive force fields, such as ReaxFF, for Molecular Dynamics (MD) simulations allowed researchers to extract mechanisms from these MD simulations. Several methods have been developed for this extraction; however, the state-of-the-art methods display some limitations making them unsuitable for the study of hydrocarbon pyrolysis. First, these methods are only appropriate for the study of small molecules; since large molecules or solid particles appear in hydrocarbon pyrolysis, a framework that can both describe short and long molecules is needed. Second, the method cannot rely on theories such as Transition State Theory that were developed for gases. Hydrocarbon pyrolysis involves liquid and solid phases making these theories inappropriate. Eventually, the mechanisms are usually fitted to some specific conditions of temperature and pressure, but no extrapolation to new conditions have been performed. These extrapolations are especially important in low-reactivity conditions (low temperature and pressure) where MD simulations cannot reach equilibrium in reasonable computational time. In this dissertation, I am presenting the developments to mechanism extraction from MD simulations that made this method suitable for hydrocarbon pyrolysis. Mechanism extraction was performed on training MD simulations of hydrocarbon pyrolysis. From these simulations, the possible reactions that can occur in this system were extracted and their reaction rates estimated. From the list of reactions in the mechanism and their associated reaction rates, the evolution of hydrocarbon pyrolysis in different conditions was predicted by running Kinetic Monte Carlo (KMC) simulations that served here as an ordinary differential equation solver. This general framework was improved during my PhD. As a first contribution, reactions were described at the atomic scale, considering only the local structure around the reactive site and ignoring the rest of the molecules. This description differs from common mechanism where the reactions are described with the full molecules. This new description allowed me to describe both short and long molecules, condense the number of reactions to describe the system, predict the appearance of molecules unobserved in the initial MD simulations, transfer to the pyrolysis of new hydrocarbons, and extrapolate MD simulations to longer timescales. My second contribution was to perform temperature extrapolation on the extracted mechanism. This extrapolation enabled me to make accurate predictions of the evolution of different hydrocarbon pyrolysis in temperatures that were outside of the temperature range of the MD simulations that were used to extract the mechanism. I was able to make accurate predictions several hundred kelvins outside of this temperature range, run simulations on the microsecond-scale that would be too long to run for an MD simulation, and give insights to some experimental results of hydrocarbon pyrolysis. My final contribution involved the development of a model that predicts the size distribution of hydrocarbon at equilibrium in many different conditions from a simplified mechanism and random graph theory. This model can give quickly and accurately the equilibrium conditions that would otherwise need an MD simulation or a KMC simulation to be predicted.
Author: Vincent Jean Louis Dufour Publisher: ISBN: Category : Languages : en Pages :
Book Description
Hydrocarbon pyrolysis is a process that is thought to occur in the interior of icy giant planets. This reaction would transform the methane contained in the interior of these planets into diamond through compression to pressure of several tens of gigapascals and heating to temperatures of several thousands of kelvins. Even if it is commonly admitted that this reaction occurs, the conditions under which it takes place are still debated. Many experiments and theoretical calculations gave disagreeing predictions; some experiments led to the observation of diamond from hydrocarbon pyrolysis in pressure as low as 10 GPa and temperatures between 2,000 and 3,000 K, whereas other experiments and theoretical predictions claimed that diamond cannot be produced by hydrocarbon pyrolysis below 100 GPa. Several explanations have been proposed to explain these discrepancies; however, there is no consensus yet and one of the main reasons is that the precise mechanism of hydrocarbon pyrolysis is not precisely known. A crude mechanism is that methane separates into dihydrogen and carbon-rich molecules, such as large hydrocarbons or solids. Nevertheless, this simplified mechanism leaves many topics unstudied: first, the kinetic of the reaction remains unknown. This limitation implies that researchers cannot guarantee that their experiments or simulations were run for a sufficient time to reach equilibrium. Another poorly understood topic is the role of pressure and temperature; it is generally assumed that diamond is more likely to be synthesized when pressure and temperature increases. But the exact conditions in which diamond is produced and the role of pressure and temperature has not been studied yet. Finally, the role of the hydrogen content has not been investigated; Le Chatelier's principle implies that the less hydrogen in the system, the larger the hydrocarbons will be, but it is unknown which hydrogen content induces diamond production. Therefore, there is a need for a detailed mechanism of hydrocarbon pyrolysis. Discovering the hydrocarbon pyrolysis mechanism through experiments is impractical because of the extreme conditions undergone and the short time scales involved. Recently, the rise of reactive force fields, such as ReaxFF, for Molecular Dynamics (MD) simulations allowed researchers to extract mechanisms from these MD simulations. Several methods have been developed for this extraction; however, the state-of-the-art methods display some limitations making them unsuitable for the study of hydrocarbon pyrolysis. First, these methods are only appropriate for the study of small molecules; since large molecules or solid particles appear in hydrocarbon pyrolysis, a framework that can both describe short and long molecules is needed. Second, the method cannot rely on theories such as Transition State Theory that were developed for gases. Hydrocarbon pyrolysis involves liquid and solid phases making these theories inappropriate. Eventually, the mechanisms are usually fitted to some specific conditions of temperature and pressure, but no extrapolation to new conditions have been performed. These extrapolations are especially important in low-reactivity conditions (low temperature and pressure) where MD simulations cannot reach equilibrium in reasonable computational time. In this dissertation, I am presenting the developments to mechanism extraction from MD simulations that made this method suitable for hydrocarbon pyrolysis. Mechanism extraction was performed on training MD simulations of hydrocarbon pyrolysis. From these simulations, the possible reactions that can occur in this system were extracted and their reaction rates estimated. From the list of reactions in the mechanism and their associated reaction rates, the evolution of hydrocarbon pyrolysis in different conditions was predicted by running Kinetic Monte Carlo (KMC) simulations that served here as an ordinary differential equation solver. This general framework was improved during my PhD. As a first contribution, reactions were described at the atomic scale, considering only the local structure around the reactive site and ignoring the rest of the molecules. This description differs from common mechanism where the reactions are described with the full molecules. This new description allowed me to describe both short and long molecules, condense the number of reactions to describe the system, predict the appearance of molecules unobserved in the initial MD simulations, transfer to the pyrolysis of new hydrocarbons, and extrapolate MD simulations to longer timescales. My second contribution was to perform temperature extrapolation on the extracted mechanism. This extrapolation enabled me to make accurate predictions of the evolution of different hydrocarbon pyrolysis in temperatures that were outside of the temperature range of the MD simulations that were used to extract the mechanism. I was able to make accurate predictions several hundred kelvins outside of this temperature range, run simulations on the microsecond-scale that would be too long to run for an MD simulation, and give insights to some experimental results of hydrocarbon pyrolysis. My final contribution involved the development of a model that predicts the size distribution of hydrocarbon at equilibrium in many different conditions from a simplified mechanism and random graph theory. This model can give quickly and accurately the equilibrium conditions that would otherwise need an MD simulation or a KMC simulation to be predicted.
Author: David B. Kirk Publisher: Newnes ISBN: 0123914183 Category : Computers Languages : en Pages : 519
Book Description
Programming Massively Parallel Processors: A Hands-on Approach, Second Edition, teaches students how to program massively parallel processors. It offers a detailed discussion of various techniques for constructing parallel programs. Case studies are used to demonstrate the development process, which begins with computational thinking and ends with effective and efficient parallel programs. This guide shows both student and professional alike the basic concepts of parallel programming and GPU architecture. Topics of performance, floating-point format, parallel patterns, and dynamic parallelism are covered in depth. This revised edition contains more parallel programming examples, commonly-used libraries such as Thrust, and explanations of the latest tools. It also provides new coverage of CUDA 5.0, improved performance, enhanced development tools, increased hardware support, and more; increased coverage of related technology, OpenCL and new material on algorithm patterns, GPU clusters, host programming, and data parallelism; and two new case studies (on MRI reconstruction and molecular visualization) that explore the latest applications of CUDA and GPUs for scientific research and high-performance computing. This book should be a valuable resource for advanced students, software engineers, programmers, and hardware engineers. - New coverage of CUDA 5.0, improved performance, enhanced development tools, increased hardware support, and more - Increased coverage of related technology, OpenCL and new material on algorithm patterns, GPU clusters, host programming, and data parallelism - Two new case studies (on MRI reconstruction and molecular visualization) explore the latest applications of CUDA and GPUs for scientific research and high-performance computing
Author: Michael Springborg Publisher: Royal Society of Chemistry ISBN: 1839162651 Category : Science Languages : en Pages : 196
Book Description
Chemical modelling covers a wide range of disciplines and this book is the first stop for any materials scientist, biochemist, chemist or molecular physicist wishing to acquaint themselves with major developments in the applications and theory of chemical modelling. Containing both comprehensive and critical reviews, it is a convenient reference to the current literature. Coverage includes, but is not limited to, isomerism in polyoxometalate chemistry, modelling molecular magnets, molecular modelling of cyclodextrin inclusion complexes and graphene nanoribbons heterojunctions.
Author: Papu Kumar Naik Publisher: ISBN: 9781032138589 Category : Eutectics Languages : en Pages : 0
Book Description
"Deep Eutectic Solvents (DES) are new class of green solvents that opens a whole new world of opportunities for separation challenges. This book comprehensively provides a detailed discussion of their application as an extractive solvent in separation processes, adopting Molecular Dynamics (MD) simulations for atomistic insight into the solute transfer across bi-phasic systems. Further, it explains ternary and quaternary mixtures, including molecular dynamics simulation of relevant DES systems. Features: Covers application of Deep Eutectic Solvents (DES) in extraction of aromatics and polyaromatics from fuel oil by Liquid-Liquid extraction. Studies eutectic behavior with respect to hydrocarbon and aqueous solutions. Describes molecular dynamics insights of extraction by DES. Explores possible industrial applicability of potential DES. Includes results from Gaussian, NAMD and PACKMOL software package. This book aims at Researchers and Graduate students in Fuels and Petrochemicals, Separation Science, Chromatography, Chemical Processing and Design"--
Author: Christophe Chipot Publisher: Springer Science & Business Media ISBN: 3540384472 Category : Language Arts & Disciplines Languages : en Pages : 528
Book Description
Free energy constitutes the most important thermodynamic quantity to understand how chemical species recognize each other, associate or react. Examples of problems in which knowledge of the underlying free energy behaviour is required, include conformational equilibria and molecular association, partitioning between immiscible liquids, receptor-drug interaction, protein-protein and protein-DNA association, and protein stability. This volume sets out to present a coherent and comprehensive account of the concepts that underlie different approaches devised for the determination of free energies. The reader will gain the necessary insight into the theoretical and computational foundations of the subject and will be presented with relevant applications from molecular-level modelling and simulations of chemical and biological systems. Both formally accurate and approximate methods are covered using both classical and quantum mechanical descriptions. A central theme of the book is that the wide variety of free energy calculation techniques available today can be understood as different implementations of a few basic principles. The book is aimed at a broad readership of graduate students and researchers having a background in chemistry, physics, engineering and physical biology.
Author: Thomas S. Hofer Publisher: Frontiers Media SA ISBN: 2889456269 Category : Languages : en Pages : 188
Book Description
The QM/MM method, short for quantum mechanical/molecular mechanical, is a highly versatile approach for the study of chemical phenomena, combining the accuracy of quantum chemistry to describe the region of interest with the efficiency of molecular mechanical potentials to represent the remaining part of the system. Originally conceived in the 1970s by the influential work of the the Nobel laureates Martin Karplus, Michael Levitt and Arieh Warshel, QM/MM techniques have evolved into one of the most accurate and general approaches to investigate the properties of chemical systems via computational methods. Whereas the first applications have been focused on studies of organic and biomolecular systems, a large variety of QM/MM implementations have been developed over the last decades, extending the range of applicability to address research questions relevant for both solution and solid-state chemistry as well. Despite approaching their 50th anniversary in 2022, the formulation of improved QM/MM methods is still an active field of research, with the aim to (i) extend the applicability to address an even broader range of research questions in chemistry and related disciplines, and (ii) further push the accuracy achieved in the QM/MM description beyond that of established formulations. While being a highly successful approach on its own, the combination of the QM/MM strategy with other established theoretical techniques greatly extends the capabilities of the computational approaches. For instance the integration of a suitable QM/MM technique into the highly successful Monte-Carlo and molecular dynamics simulation protocols enables the description of the chemical systems on the basis of an ensemble that is in part constructed on a quantum-mechanical basis. This eBook presents the contributions of a recent Research Topic published in Frontiers in Chemistry, that highlight novel approaches as well as advanced applications of QM/MM method to a broad variety of targets. In total 2 review articles and 10 original research contributions from 48 authors are presented, covering 12 different countries on four continents. The range of research questions addressed by the individual contributions provide a lucid overview on the versatility of the QM/MM method, and demonstrate the general applicability and accuracy that can be achieved for different problems in chemical sciences. Together with the development of improved algorithms to enhance the capabilities of quantum chemical methods and the continuous advancement in the capacities of computational resources, it can be expected that the impact of QM/MM methods in chemical sciences will be further increased already in the near future.
Author: Adriano D. Andricopulo Publisher: Frontiers Media SA ISBN: 2889457443 Category : Languages : en Pages : 415
Book Description
Chemoinformatics is paramount to current drug discovery. Structure- and ligand-based drug design strategies have been used to uncover hidden patterns in large amounts of data, and to disclose the molecular aspects underlying ligand-receptor interactions. This Research Topic aims to share with a broad audience the most recent trends in the use of chemoinformatics in drug design. To that end, experts in all areas of drug discovery have made their knowledge available through a series of articles that report state-of-the-art approaches. Readers are provided with outstanding contributions focusing on a wide variety of topics which will be of great value to those interested in the many different and exciting facets of drug design.
Author: Michael Springborg Publisher: Royal Society of Chemistry ISBN: 1849739544 Category : Science Languages : en Pages : 210
Book Description
In a field as diverse as Chemical Modelling it can be difficult to keep up with the literature, or discover the latest applications of computational and theoretical chemistry. Specialist Periodical Reports present comprehensive and critical reviews of the recent literature, providing the reader with informed opinion and latest detailed information in their field. The latest volume of Chemical Modelling presents a diverse range of authors invited by the volume editors. Topics include Quantum Chemistry of Large Systems, Theoretical Studies of Special Relativity in Atoms and Molecules, MOFs: From Theory Towards Applications, and Multi-Scale Modelling. Other chapters look at Catalysis, Descriptive DFT, Phase Transitions. An essential resource for experienced researchers and those just entering the field of chemical modelling, this latest Specialist Periodical Report is an essential resource for any research group active in the field or chemical sciences library.
Author: Defang Ouyang Publisher: John Wiley & Sons ISBN: 1118573994 Category : Science Languages : en Pages : 350
Book Description
Molecular modeling techniques have been widely used in drug discovery fields for rational drug design and compound screening. Now these techniques are used to model or mimic the behavior of molecules, and help us study formulation at the molecular level. Computational pharmaceutics enables us to understand the mechanism of drug delivery, and to develop new drug delivery systems. The book discusses the modeling of different drug delivery systems, including cyclodextrins, solid dispersions, polymorphism prediction, dendrimer-based delivery systems, surfactant-based micelle, polymeric drug delivery systems, liposome, protein/peptide formulations, non-viral gene delivery systems, drug-protein binding, silica nanoparticles, carbon nanotube-based drug delivery systems, diamond nanoparticles and layered double hydroxides (LDHs) drug delivery systems. Although there are a number of existing books about rational drug design with molecular modeling techniques, these techniques still look mysterious and daunting for pharmaceutical scientists. This book fills the gap between pharmaceutics and molecular modeling, and presents a systematic and overall introduction to computational pharmaceutics. It covers all introductory, advanced and specialist levels. It provides a totally different perspective to pharmaceutical scientists, and will greatly facilitate the development of pharmaceutics. It also helps computational chemists to look for the important questions in the drug delivery field. This book is included in the Advances in Pharmaceutical Technology book series.
Author: Zaheer Ul-Haq Publisher: Elsevier ISBN: 1608058646 Category : Science Languages : en Pages : 364
Book Description
Frontiers in Computational Chemistry, originally published by Bentham and now distributed by Elsevier, presents the latest research findings and methods in the diverse field of computational chemistry, focusing on molecular modeling techniques used in drug discovery and the drug development process. This includes computer-aided molecular design, drug discovery and development, lead generation, lead optimization, database management, computer and molecular graphics, and the development of new computational methods or efficient algorithms for the simulation of chemical phenomena including analyses of biological activity. In Volume 1, the leading researchers in the field have collected eight different perspectives in the application of computational methods towards drug design to provide an up-to-date rendering of the current field. This volume covers a variety of topics from G protein-coupled receptors, to the use of cheminformatics and bioinformatics, computational tools such as Molecular Mechanics Poisson-Boltzmann Surface Area, protein-protein interactions, the use of computational methods on large biological data sets, various computational methods used to identify pharmaceutically relevant targets, and more. Brings together a wide range of research into a single collection to help researchers keep up with new methods Uniquely focuses on computational chemistry approaches that can accelerate drug design Makes a solid connection between experiment and computation and the novel application of computational methods in the fields of biology, chemistry, biochemistry, physics, and biophysics, with particular focus on the integration of computational methods with experimental data
Author: Vincent Jean Louis Dufour
Author: Vincent Jean Louis Dufour
Author: David B. Kirk
Author: Michael Springborg
Author: Papu Kumar Naik
Author: Christophe Chipot
Author: Thomas S. Hofer
Author: Adriano D. Andricopulo
Author: Michael Springborg
Author: Defang Ouyang
Author: Zaheer Ul-Haq