Mathematica Solution for Materials Science

INDUSTRY SOLUTIONS FOR SCIENCE MATERIALS SCIENCE Other Mathematica Solutions » Data Analysis and Mining » Chemical Engineering » Mechanical Engineering » Other Mathematica Solutions » Model new materials using powerful symbolic and numeric computational abilities, visualize crystal structures interactively, and measure performance by analyzing deformation and failure data with sophisticated statistics—all in one integrated workflow. Underlying the Mathematica materials science solution is the most automated and reliable computation, development, and deployment environment available. Designing new materials and processes using powerful computational abilities Sample models of an anisotropically elastic solid; a diffusion-limited aggregation process; and a folded structure, such as a core for a lightweight panel Characterizing materials or analyzing performance with original algorithms Simple, interactive curve-fitting tools that can be easily created and shared Using built-in connectivity, integration, and interactivity A notebook instantly converted to an interactive slide show that can be modified during a presentation KEY CAPABILITIES WHY CHOOSE MATHEMATICA WAYS TO USE Mathematica includes thousands of built-in functions for computation, modeling, visualization, development, and deployment » Materials science specific capabilities: Powerful differential equation solvers to model and design new materials with specified properties or structures » Create reusable models of material performance or processing methods with symbolic computations; use numerical computations when equations can't be solved symbolically Build interactive tools for optimizing models by instantly viewing the effects of changing parameters » Built-in calculus abilities for computing complicated integrals to determine properties of materials at boundaries » Import and export of common scientific data formats, including HDF5, PDB, MOL, SDF, TSV, and CSV » Easy programmability lets you automate data analysis to speed characterization of new materials or convert formulas to code that controls manufacturing equipment » Built-in statistical analysis and curve-fitting functions and probability distributions for data analysis » Use Mathematica's built-in structural and chemical data in your work Lattice Data » Get images and structural properties of named lattices Polyhedron Data » Get information on the geometry and properties of polyhedra Chemical Data » Get structural, physical, and other properties of chemical compounds Built-in image processing functions, including edge detection and filtering, to identify deformation or defects with microscopy » Linear and nonlinear optimization abilities, including the interior-point method, constrained nonlinear optimization, and more to optimize the structure of new materials » Highly customized, presentation-quality interactive graphics, with a large variety of powerful visualization functions » Built-in connectivity to databases, web services, existing C++ code, other commercial programs, and Java and .NET frameworks » Multicore computing, 64-bit technology, and built-in parallel processing for work on large datasets or complex calculations » KEY CAPABILITIES WHY CHOOSE MATHEMATICA WAYS TO USE Compare Mathematica to your current tools. Do they have these advantages? Symbolic calculations improve the accuracy and flexibility of structural or performance models Competitor note: Matlab's built-in routines only handle numeric calculations Gain accuracy in predicting behavior at small length scales with built-in, fully automated precision control and arbitrary-precision arithmetic » Competitor note: Excel, Matlab, and other systems relying on machine arithmetic can show critical errors due to numerical accuracy failure Choose from procedural, functional, and rule-based programming paradigms for fast development of analysis tools or theoretical models » Competitor note: Mathcad only has a simple procedural programming language built in Import, compute, and deliver results in one interactive document instead of across several applications » Competitor note: Matlab does not have a built-in document system KEY CAPABILITIES WHY CHOOSE MATHEMATICA WAYS TO USE Calculate the expected stresses and strains a material will feel as it is deformed and analyze deformation data to determine its stiffness and strength Post-process derived equations to convert them to code that will control machining equipment Instantly create interactive tools for data analysis, presentation, or sharing ideas with colleagues and deploy them to others with the Mathematica Player family » Solve complex analytic geometry problems to design new structures Model and analyze future measurement or manufacturing equipment for semiconductor production Design, test, and manufacture lightweight and strong materials » Study the effects of different processing techniques on material properties Apply computational quantum mechanics to design new materials Construct crystal models with built-in lattice and polyhedron data structures » MATERIALS SCIENCE CASE STUDIES Case Studies A Bottle of Soap, A Bar of Shampoo? » Mathematica in Furtive Fighters and Squashed Sidelobes » Putting Cotton to the Test » Some Major Organizations Using Mathematica Air Force Research Laboratory Alliant Techsystems, Inc. Applied Research Laboratory at Penn State Argonne National Laboratory Bosch Brookhaven National Laboratory CNRS Corning, Inc. EMPA Hahn-Meitner Institut Honeywell Intel Japan Institute of Sports Sciences Laboratoire Leon Brillouin Los Alamos National Lab Max Planck Institute National Institute for Materials Science Oak Ridge National Laboratory Weierstrass Institute for Applied Analysis and Stochastics RELATED DOCUMENTATION Guides to Mathematica's Materials Science Capabilities Calculus » Integral Transforms » Matrices and Linear Algebra » Matrix Operations » Image Processing & Analysis » Curve Fitting & Approximate Functions » Statistics » Handling Arrays of Data » Numerical Data » Importing & Exporting » Computable Data » Data Visualization » Graphics Options & Styling » Tutorials on Using Mathematica for Materials Science Tasks Special Functions » Eigenvalues and Eigenvectors » Vectors and Matrices » Basic Matrix Operations » Tensors » Calculus » Integration » Differential Equations » Numerical Calculations » How to Do Statistics » Importing and Exporting Data » Importing Graphics and Sound » Manipulating Numerical Data » Curve Fitting » In-depth Information on Mathematica's Materials Science Functions `Solve` » `FindRoot` » `Eigensystem` » `Array` » `Det` » `Tr` » `Integrate` » `D` » `DSolve` » `Fit` » `FindFit` » `Import` » `Histogram` » `RegionFunction` » More Documentation » OTHER RESOURCES Books Elasticity with Mathematica: An Introduction to Continuum Mechanics and Linear Elasticity » Continuum Mechanics using Mathematica: Fundamentals, Applications, and Scientific Computing » Sculptured Thin Films: Nanoengineered Morphology and Optics » Exploring Scanning Probe Microscopy with Mathematica, Second Edition » More Books » Articles and Presentations Modeling Stochastic Fibrous Materials with Mathematica: Intrinsic Correlation in Planar Poisson Line Processes » Calculation of X-ray Wave Fields in Perfect Crystals by Applying Riemann's Method to Solve the Takagi-Taupin Equations » Simulation and Interpretation of 2D Diffraction Patterns from Self-Assembled Nanostructured Films at Arbitrary Angles of Incidence: From Grazing Incidence (Above the Critical Angle) to Transmission Perpendicular to the Substrate » Calculation of Material Properties and Ray Tracing in Transformation Media » Property Predictions for Textile Composites » A Computer Program Written in Mathematica for Calculating H/sub 2/ Quasicrystals and Their Diffraction Patterns » More Articles and Presentations » GET STARTED WITH MATHEMATICA Watch a Tutorial Screencast Introducing Interactive Image Processing with Mathematica » Presenting in Notebooks » Utilizing Mathematica's Integrated Data » More Screencasts » Attend a Free Online Seminar S10: A Brief Overview of Mathematica » S18: Import and Export Data Formats in Mathematica » S24: Working with Imported Data in Mathematica » More Seminars » Enroll in a Course M101: A First Course in Mathematica » M215: Applied Statistical Analysis » M221: Introduction to Programming in Mathematica » More Courses » INTERACTIVE MATERIALS SCIENCE EXAMPLES Sample Demonstrations Contributed by Users The Seven Crystal Classes (educational) » Work-Hardening Models » Weibull Statistics for Fracture Data » Vickers Hardness of Materials (educational) » Doped Silicon Semiconductors » Diamond Lattice (educational) » Deep Drawing of Metals (educational) » Anisotropic Elasticity » Elasticity of Shear (educational) » Diffusion-Limited Aggregation (educational) » Idealized Hoppering (educational) » View All » Download Free Player Here »

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