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001433315 0247_ $$a10.1007/978-981-15-9235-5$$2doi
001433315 035__ $$aSP(OCoLC)1229071356
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001433315 049__ $$aISEA
001433315 050_4 $$aQD461
001433315 08204 $$a541/.28$$223
001433315 24500 $$aRecent advances of the fragment molecular orbital method :$$benhanced performance and applicability /$$cYuji Mochizuki, Shigenori Tanaka, Kaori Fukuzawa, editors.
001433315 260__ $$aSingapore :$$bSpringer,$$c2021.
001433315 300__ $$a1 online resource
001433315 336__ $$atext$$btxt$$2rdacontent
001433315 337__ $$acomputer$$bc$$2rdamedia
001433315 338__ $$aonline resource$$bcr$$2rdacarrier
001433315 347__ $$atext file
001433315 347__ $$bPDF
001433315 5050_ $$aPart 1: Positioning of FMO -- Fragment molecular orbital method as cluster expansion -- Comparison of various fragmentation methods for quantum chemical calculations of large molecular systems -- Part 2: Programs -- Recent development of the fragment molecular orbital method in GAMESS -- The ABINIT-MP program -- PAICS: Development of An Open-Source Software of Fragment Molecular Orbital Method for Biomolecule -- Open-Architecture Program of Fragment Molecular Orbital Method for Massive Parallel Computing (OpenFMO) with GPU Acceleration -- Part 3: Pharmaceutical activities -- How to perform FMO calculation in Drug Discovery -- FMO drug design consortium -- Development of an automated FMO calculation protocol to construction of FMO database -- Application of FMO to ligand design: SBDD, FBDD, and protein-protein interaction -- Drug Discovery Screening by Combination of X-ray Crystal Structure Analysis and FMO Calculation -- Cooperative study combining X-ray crystal structure analysis and FMO calculation: Interaction analysis of FABP4 inhibitors -- Application of FMO for protein-ligand binding affinity prediction -- Recent Advances of In Silico Drug Discovery: Integrated Systems of Informatics and Simulation -- Pharmaceutical Industry -- Academia Cooperation -- Elucidating the efficacy of clinical drugs using FMO -- Application of Fragment Molecular Orbital Calculations to Functional Analysis of Enzymes -- AnalysisFMO toolkit: A PyMOL plugin for 3D-visualization of interaction energies in proteins (3D-VIEP) calculated by the FMO method -- Part 4: New methods and applications -- FMO interfaced with Molecular Dynamics simulation -- Linear Combination of Molecular Orbitals of Fragments (FMO-LCMO) Method: Its Application to Charge Transfer Studies -- Modeling of solid and surface -- Development of the analytic second derivatives for the fragment molecular orbital method -- The FMO-DFTB Method -- Self-consistent treatment of solvation structure with electronic structure based on 3D-RISM theory -- New methodology and framework -- New methodology and framework Information science-assisted analysis of FMO results for Drug Design -- Extension to multiscale simulations -- FMO-based investigations of excited-state dynamics in molecular aggregates -- Application of the fragment molecular orbital method to organic charge transport materials in xerography: a feasibility study and a charge mobility analysis -- Group molecular orbital method and Python-based programming approach -- Multi-level parallelization of the fragment molecular orbital method in GAMESS.
001433315 506__ $$aAccess limited to authorized users.
001433315 520__ $$aThis book covers recent advances of the fragment molecular orbital (FMO) method, consisting of 5 parts and a total of 30 chapters written by FMO experts. The FMO method is a promising way to calculate large-scale molecular systems such as proteins in a quantum mechanical framework. The highly efficient parallelism deserves being considered the principal advantage of FMO calculations. Additionally, the FMO method can be employed as an analysis tool by using the inter-fragment (pairwise) interaction energies, among others, and this feature has been utilized well in biophysical and pharmaceutical chemistry. In recent years, the methodological developments of FMO have been remarkable, and both reliability and applicability have been enhanced, in particular, for non-bio problems. The current trend of the parallel computing facility is of the many-core type, and adaptation to modern computer environments has been explored as well. In this book, a historical review of FMO and comparison to other methods are provided in Part I (two chapters) and major FMO programs (GAMESS-US, ABINIT-MP, PAICS and OpenFMO) are described in Part II (four chapters). dedicated to pharmaceutical activities (twelve chapters). A variety of new applications with methodological breakthroughs are introduced in Part IV (six chapters). Finally, computer and information science-oriented topics including massively parallel computation and machine learning are addressed in Part V (six chapters). Many color figures and illustrations are included. Readers can refer to this book in its entirety as a practical textbook of the FMO method or read only the chapters of greatest interest to them.
001433315 588__ $$aOnline resource; title from PDF title page (SpringerLink, viewed March 3, 2021).
001433315 650_0 $$aMolecular orbitals$$xMathematical models.
001433315 650_0 $$aQuantum chemistry.
001433315 650_6 $$aOrbitales moléculaires$$xModèles mathématiques.
001433315 650_6 $$aChimie quantique.
001433315 655_0 $$aElectronic books.
001433315 7001_ $$aMochizuki, Yuji,$$eeditor.
001433315 7001_ $$aTanaka, Shigenori,$$eeditor.
001433315 7001_ $$aFukuzawa, Kaori,$$eeditor.
001433315 77608 $$iPrint version:$$z9811592349$$z9789811592348$$w(OCoLC)1193113094
001433315 852__ $$bebk
001433315 85640 $$3Springer Nature$$uhttps://univsouthin.idm.oclc.org/login?url=https://link.springer.com/10.1007/978-981-15-9235-5$$zOnline Access$$91397441.1
001433315 909CO $$ooai:library.usi.edu:1433315$$pGLOBAL_SET
001433315 980__ $$aBIB
001433315 980__ $$aEBOOK
001433315 982__ $$aEbook
001433315 983__ $$aOnline
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