Listing 1 - 3 of 3 |
Sort by
|
Choose an application
This Special Issue gathers research from different branches of science and engineering disciplines working on experiments and modelling of nanocomposites into one volume. The Guest Editor welcomes papers dedicated to experimental, computational, and theoretical aspects dealing with many important state-of-the-art technologies and methodologies regarding the synthesis, fabrication, characterization, properties, design, and applications, and both finite element analysis and molecular dynamic simulations, of nanocomposite materials and structures. Full papers covering novel topics, extending the frontiers of the science and technology of nanoreinforced composites are encouraged. Reviews covering topics of major interest will be also considered.
ab initio --- critical yield strength --- carbon nanotube --- impact buckling --- elasticity --- molecular dynamics simulation --- magnetism --- coarse-grained model --- 3D fiber-metal laminates --- mechanical property --- interface --- nanocomposites --- interface force fields --- YN --- graphene/Fe composite --- cohesive element --- stability --- ScN --- delamination propagation --- interfaces --- graphene nanoplatelets --- nanoindentation --- pressure --- molecular dynamics --- piezoelectric property --- temperature effect --- Fe-Al --- hardness --- equivalent fiber --- disorder --- Fe3Al --- elastic modulus --- delamination buckling --- CNT agglomeration --- CNTs/epoxy nanocomposites --- boron nitride honeycomb
Choose an application
The microstructures of both martensite and bainite, although sharing some common features, depict a plethora of subtle differences that made them unique when studied in further detail. Tailoring the final properties of a microstructure based on one or the other as well as in combination with others and exploring more sophisticated concepts, such as Q&P and nanostructured bainite, are the topics which are the focus of research around the world. In understanding the key microstructural parameters controlling the final properties as well as definition of adequate process parameters to attain the desired microstructures requires that a proper understanding of the mechanism ruling their transformation and a detailed characterization first be acheived. The development of new and powerful scientific techniques and equipment (EBSD, APT, HRTEM, etc.) allow us to gain fundamental insights that help to establish some of the principles by which those microstructures are known. The developments accompanying such findings lead to further developments and intensive research providing the required metallurgical support.
n/a --- TRIP --- tempering --- modeling --- microstructure --- nanobainite --- lenticular martensite --- stainless steel --- carbonitrides precipitation --- carbide precipitation --- bainitic ferrite --- EBSD --- hot rolling --- fatigue --- transmission Kikuchi diffraction --- transmission electron microscopy --- medium-Mn steel --- dilatometry --- industrialization --- molybdenum --- ausforming --- offshore steels --- welding --- Q& --- creep resistant steels --- inductive measurements --- metastable austenite --- retained austenite --- mechanical properties --- martensite --- carbon partitioning --- transformation induced plasticity (TRIP) --- thermomechanical treatment --- phase transformation --- transformation kinetics --- kinetics --- MX nanoprecipitates --- phase equilibrium --- steel --- electron backscattering diffraction --- titanium --- impact toughness --- surface modification --- bainitic/martensitic ferrite --- retained austenite stability --- dilatation behavior --- P --- tempered martensite embrittlement --- yield strength --- bainite --- high strength steel --- tensile ductility --- synchrotron --- niobium --- microalloyed steels --- ultrahigh strength steel --- low temperature bainite --- strain-induced martensite --- plate thickness --- ferritic/martensitic steel --- austenite decomposition --- nitrocarburising --- high carbon steels --- Kernel average misorientation --- austempering --- martensitic steel --- HEXRD --- direct quenched
Choose an application
This book covers a wide range of topics in the orthopaedic fields and can be used as a textbook for the final undergraduate engineering course or as a topic on tribology at the postgraduate level. This book can serve as a useful reference for academics, tribology, and materials researchers; mechanical, materials, and physics engineers; biomedical scientists and professionals in tribology; and related industries. The scientific interest in this book will be evident for many important centres of research, including laboratories and universities throughout the world.
History of engineering & technology --- vitamin-E stabilized PE --- cross-linked PE --- standard PE --- hip simulator --- FTIR analysis --- Ti-28Nb-35.4 alloy --- powder metallurgy --- ball milling --- mechanical properties --- biocompatibility --- total hip arthroplasty --- musculoskeletal multibody model --- dynamic loading --- finite element analysis --- radial clearance --- dry and wet friction --- digital image correlation --- homogeneous strain --- small deformation level --- accuracy --- precision --- calcium phosphate cements --- polarization --- CoCr alloy --- wear particles --- hyaluronic acid --- macrophages biocompatibility --- UHMWPE --- tribology --- h-index --- bibliometric indicators --- biomaterials --- quality of research --- citations --- ceramic --- friction --- hip --- implants --- polyethylene --- prosthesis --- simulator --- wear --- mandible condylar fractures --- surgical treatment --- titanium --- PLLA --- Selective Laser Melting --- Direct Metal Laser Sintering --- porosity --- titanium alloys --- yield strength --- ultimate tensile strength --- X-Ray Diffraction --- n/a --- computational model --- biomechanics --- unicompartmental knee replacement --- CFR-PEEK --- varus and valgus alignments --- bioceramics --- additive manufacturing --- scaffolds --- bone tissue engineering
Listing 1 - 3 of 3 |
Sort by
|