Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

Composites can be engineered to exhibit high strength, high stiffness, and high toughness. Composite structures have increasingly been used in various engineering applications. In recent decades, most fundamentals of science have expanded in length by many orders of magnitude. Nowadays, one of the primary goals of science and technology seems to be to develop reliable methods for linking the physical phenomena that occur over multiple length scales, particularly from a nano-/microscale to a macroscale. To engineer composites for high performance and to design advanced structures, the relationship between material nano-/microstructures and their macroscopic properties must be established to accurately predict their mechanical performance and failure. Multiscale simulation is a tool that enables studying and comprehending complex systems and phenomena that would otherwise be too expensive or dangerous, or even impossible, to study by direct experimentation and, thus, to achieve this goal.This reprint assembles high-quality chapters that advance the field of the multiscale simulation of composite structures, through the application of any modern computational and/or analytical methods alone or in conjunction with experimental techniques, for damage assessment or mechanical analysis and prediction.

Life sciences. --- Biosciences --- Sciences, Life --- Science

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

Composites have been increasingly used in various structural components in the aerospace, marine, automotive, and wind energy sectors. Composites' material characterization is a vital part of the product development and production process. Physical, mechanical, and chemical characterization helps developers to further their understanding of products and materials, thus ensuring quality control. Achieving an in-depth understanding and consequent improvement of the general performance of these materials, however, still requires complex material modeling and simulation tools, which are often multiscale and encompass multiphysics. This Special Issue is aimed at soliciting promising, recent developments in composite modeling, simulation, and characterization, in both design and manufacturing areas, including experimental as well as industrial-scale case studies. All submitted manuscripts will undergo a rigorous review and will only be considered for publication if they meet journal standards.

Chemical engineering.

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

Composites have increasingly been used in various structural components in the aerospace, marine, automotive, and wind energy sectors. The material characterization of composites is a vital part of the product development and production process. Physical, mechanical, and chemical characterization helps developers to further their understanding of products and materials, thus ensuring quality control. Achieving an in-depth understanding and consequent improvement of the general performance of these materials, however, still requires complex material modeling and simulation tools, which are often multiscale and encompass multiphysics. This Special Issue aims to solicit papers concerning promising, recent developments in composite modeling, simulation, and characterization, in both design and manufacturing areas, including experimental as well as industrial-scale case studies. All submitted manuscripts will undergo a rigorous review process and will only be considered for publication if they meet journal standards. Selected top articles may have their processing charges waived at the recommendation of reviewers and the Guest Editor.

Research & information: general --- structural dynamics --- composite plastics --- stiffness --- damping --- fiber orientation --- ODF --- viscoelasticity --- geopolymer concrete --- fly-ash --- bottom-ash --- freeze-thaw --- leachability --- non-destructive test --- TCLP --- RFT --- fiber matrix interface --- finite element analysis --- characterization --- composite --- measurements --- testing --- structural monitoring --- flax-epoxy composite --- interlaminar fracture energy --- fracture toughness --- delamination --- Mode I --- Mode II and Mixed-mode I-II interlaminar fracture --- critical energy release rate --- machine learning --- mould filling simulations --- composite materials --- liquid moulding --- lattice cell structures --- InsideBCC --- equivalent solid properties --- three-dimensional printing --- nacre --- hexagonal tablets --- analytical model --- finite element simulations --- Abaqus --- fused filament fabrication --- PLA --- bamboo --- mechanical strength --- damage detection --- laminated composite plates --- modal analysis --- curvature mode shape --- strain energy --- structural dynamics --- composite plastics --- stiffness --- damping --- fiber orientation --- ODF --- viscoelasticity --- geopolymer concrete --- fly-ash --- bottom-ash --- freeze-thaw --- leachability --- non-destructive test --- TCLP --- RFT --- fiber matrix interface --- finite element analysis --- characterization --- composite --- measurements --- testing --- structural monitoring --- flax-epoxy composite --- interlaminar fracture energy --- fracture toughness --- delamination --- Mode I --- Mode II and Mixed-mode I-II interlaminar fracture --- critical energy release rate --- machine learning --- mould filling simulations --- composite materials --- liquid moulding --- lattice cell structures --- InsideBCC --- equivalent solid properties --- three-dimensional printing --- nacre --- hexagonal tablets --- analytical model --- finite element simulations --- Abaqus --- fused filament fabrication --- PLA --- bamboo --- mechanical strength --- damage detection --- laminated composite plates --- modal analysis --- curvature mode shape --- strain energy