01051nam a2200301 i 450099100099120970753620020507181232.0930702s1990 us ||| | eng 0201509431b10785978-39ule_instLE01305402ExLDip.to Matematicaeng511.6AMS 05-01AMS 05-XXQA164.S56Skiena, Steven286246Implementing discrete mathematics :combinatorics and graph theory with mathematica /Steven SkienaRedwood City, California :Addison-Wesley,1990x, 334 p. ;24 cm.Combinatorial analysisGraph theory.b1078597821-09-0628-06-02991000991209707536LE013 05-XX SKI11 (1990)12013000146690le013-E0.00-l- 02020.i1088617528-06-02Implementing discrete mathematics752020UNISALENTOle01301-01-93ma -engus 0103890nam 22005415 450 991029842260332120200701185547.03-658-21134-210.1007/978-3-658-21134-9(CKB)4100000002485510(MiAaPQ)EBC5311262(DE-He213)978-3-658-21134-9(PPN)22463755X(EXLCZ)99410000000248551020180224d2018 u| 0engurcnu||||||||rdacontentrdamediardacarrierMultiscale Modeling and Simulation of Shock Wave-Induced Failure in Materials Science /by Martin Oliver Steinhauser1st ed. 2018.Wiesbaden :Springer Fachmedien Wiesbaden :Imprint: Springer Spektrum,2018.1 online resource (84 pages) illustrations, tablesResearch3-658-21133-4 Includes bibliographical references and index.Definition of Shock Waves -- Multiscale Modeling and Simulation in Hard Matter -- Shock Wave Failure in Granular Materials -- Coarse-Grained Modeling and Simulation of Macromolecules -- Laser-Induced Shock Wave Failure in Human Cancer Cells -- The Future of Multiscale Materials Modeling.Martin Oliver Steinhauser deals with several aspects of multiscale materials modeling and simulation in applied materials research and fundamental science. He covers various multiscale modeling approaches for high-performance ceramics, biological bilayer membranes, semi-flexible polymers, and human cancer cells. He demonstrates that the physics of shock waves, i.e., the investigation of material behavior at high strain rates and of material failure, has grown to become an important interdisciplinary field of research on its own. At the same time, progress in computer hardware and software development has boosted new ideas in multiscale modeling and simulation. Hence, bridging the length and time scales in a theoretical-numerical description of materials has become a prime challenge in science and technology. Contents Definition of Shock Waves Multiscale Modeling and Simulation in Hard Matter Shock Wave Failure in Granular Materials Coarse-Grained Modeling and Simulation of Macromolecules Laser-Induced Shock Wave Failure in Human Cancer Cells The Future of Multiscale Materials Modeling Target Groups Researchers and students in the fields of (bio-)physics, computational science, materials engineering, materials science, computer science, polymer chemistry, theoretical chemistry, nanoscience Material scientists, engineers The Author Dr. Martin O. Steinhauser works as Senior Scientist and Principal Investigator at the Fraunhofer Institute for High-Speed Dynamics/Ernst-Mach-Institut (EMI) in Freiburg, Germany. .Research (Wiesbaden, Germany)CancerResearchCheminformaticsPhysicsCancer Researchhttps://scigraph.springernature.com/ontologies/product-market-codes/B11001Computer Applications in Chemistryhttps://scigraph.springernature.com/ontologies/product-market-codes/C13009Numerical and Computational Physics, Simulationhttps://scigraph.springernature.com/ontologies/product-market-codes/P19021CancerResearch.Cheminformatics.Physics.Cancer Research.Computer Applications in Chemistry.Numerical and Computational Physics, Simulation.620.1126Steinhauser Martin Oliverauthttp://id.loc.gov/vocabulary/relators/aut916045BOOK9910298422603321Multiscale Modeling and Simulation of Shock Wave-Induced Failure in Materials Science2526742UNINA