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Interfaces play an essential role in determining the mechanical properties and the structural integrity of a wide variety of technological materials. As new manufacturing methods become available, interface engineering and architecture at multiscale length levels in multi-physics materials open up to applications with high innovation potential. This Special Issue is dedicated to recent advances in fundamental and applications of solid material interfaces.
Technology: general issues --- Kirchhoff-Love plate --- composite material --- thin inclusion --- asymptotic analysis --- equivalent cylinder of finite length --- Steigmann-Ogden surface model --- anisotropic properties --- contact problem --- unilateral constraint --- variational inequality --- Tykhonov triple --- Tykhonov well-posedness --- approximating sequence --- multiphase fiber-reinforced composites --- asymptotic homogenization method --- effective complex properties --- elastic composite --- interfaces --- coupled thermoelasticity --- adhesive layer --- butt joint --- mode-I --- mixed-mode --- damage evolution --- analytical solution
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Interfaces play an essential role in determining the mechanical properties and the structural integrity of a wide variety of technological materials. As new manufacturing methods become available, interface engineering and architecture at multiscale length levels in multi-physics materials open up to applications with high innovation potential. This Special Issue is dedicated to recent advances in fundamental and applications of solid material interfaces.
Technology: general issues --- Kirchhoff-Love plate --- composite material --- thin inclusion --- asymptotic analysis --- equivalent cylinder of finite length --- Steigmann–Ogden surface model --- anisotropic properties --- contact problem --- unilateral constraint --- variational inequality --- Tykhonov triple --- Tykhonov well-posedness --- approximating sequence --- multiphase fiber-reinforced composites --- asymptotic homogenization method --- effective complex properties --- elastic composite --- interfaces --- coupled thermoelasticity --- adhesive layer --- butt joint --- mode-I --- mixed-mode --- damage evolution --- analytical solution --- n/a --- Steigmann-Ogden surface model
Choose an application
Interfaces play an essential role in determining the mechanical properties and the structural integrity of a wide variety of technological materials. As new manufacturing methods become available, interface engineering and architecture at multiscale length levels in multi-physics materials open up to applications with high innovation potential. This Special Issue is dedicated to recent advances in fundamental and applications of solid material interfaces.
Kirchhoff-Love plate --- composite material --- thin inclusion --- asymptotic analysis --- equivalent cylinder of finite length --- Steigmann–Ogden surface model --- anisotropic properties --- contact problem --- unilateral constraint --- variational inequality --- Tykhonov triple --- Tykhonov well-posedness --- approximating sequence --- multiphase fiber-reinforced composites --- asymptotic homogenization method --- effective complex properties --- elastic composite --- interfaces --- coupled thermoelasticity --- adhesive layer --- butt joint --- mode-I --- mixed-mode --- damage evolution --- analytical solution --- n/a --- Steigmann-Ogden surface model
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With advances in dental materials and their clinical applications, as well as innovations in computer technology, dental treatment is constantly evolving. In particular, adhesion technology to the tooth surface, implant treatments, and the application of CAD/CAM technology are very interesting topics for clinical dentists. As a bonding technique, the influence of the pre-etched area of the tooth surface on the adhesive strength can be reduced by the new application of a functional monomer. Additionally, the effect of an advanced adhesive system as a universal adhesive-derived primer, when compared with the two-step adhesive, is helpful for updating the applications of new materials. Dental implants are one of the most interesting dental treatments. PEEK (polyetheretherketone) has recently been reported as a further innovation in polymer implant materials, although it has not yet met the requirements to be a biomechanical requirement. In the placement of mini-screws used in orthodontic treatments, micro-cracks caused by overtorquing in thick and hard bone, and the consequent heat production, can reduce the success rate. Computer-aided design/computer-aided manufacturing (CAD/CAM) techniques are becoming increasingly popular. Since complete dentures can be produced using an additive (3D printing) or subtractive (milling) process, CAD/CAM techniques for denture fabrication have many clinical and laboratory advantages. Innovative and convenient dental material technology will be more and more expected in the future. This book has limited findings, but we hope that your clinical capability will be integrated and upgraded.
denture base --- complete denture --- acrylic resin --- CAD-CAM --- milling resin --- eye-tracking --- aesthetics --- golden ratio --- forensics --- caries model --- Streptococcus mutans --- demineralization --- dental caries --- molar intrusion --- orthodontic treatment --- temporomandibular disorder --- occlusal splint --- centric relation --- bracket debonding --- dental enamel --- scanning electron microscopy --- orthodontics --- methacrylate monomer --- heat polymerization --- mechanical properties --- resin infiltration --- two-step adhesive system --- universal adhesive-derived primer --- adhesive layer thickness --- enamel bond durability --- orthodontic screw --- mini-implant --- pre-drilling --- heat production --- temperature --- irrigation --- cooled irrigation --- safety --- bone drilling --- orthodontic adhesive paste --- functional monomer --- pre-etched area --- chewing exercise --- masticatory function --- masticatory pattern --- open bite --- TADs --- cephalometric analysis --- treatment option criteria --- ROC analysis --- orthodontic retainer --- oral hygiene --- gingival recession --- patient compliance --- n/a
Choose an application
With advances in dental materials and their clinical applications, as well as innovations in computer technology, dental treatment is constantly evolving. In particular, adhesion technology to the tooth surface, implant treatments, and the application of CAD/CAM technology are very interesting topics for clinical dentists. As a bonding technique, the influence of the pre-etched area of the tooth surface on the adhesive strength can be reduced by the new application of a functional monomer. Additionally, the effect of an advanced adhesive system as a universal adhesive-derived primer, when compared with the two-step adhesive, is helpful for updating the applications of new materials. Dental implants are one of the most interesting dental treatments. PEEK (polyetheretherketone) has recently been reported as a further innovation in polymer implant materials, although it has not yet met the requirements to be a biomechanical requirement. In the placement of mini-screws used in orthodontic treatments, micro-cracks caused by overtorquing in thick and hard bone, and the consequent heat production, can reduce the success rate. Computer-aided design/computer-aided manufacturing (CAD/CAM) techniques are becoming increasingly popular. Since complete dentures can be produced using an additive (3D printing) or subtractive (milling) process, CAD/CAM techniques for denture fabrication have many clinical and laboratory advantages. Innovative and convenient dental material technology will be more and more expected in the future. This book has limited findings, but we hope that your clinical capability will be integrated and upgraded.
Information technology industries --- Computer science --- denture base --- complete denture --- acrylic resin --- CAD-CAM --- milling resin --- eye-tracking --- aesthetics --- golden ratio --- forensics --- caries model --- Streptococcus mutans --- demineralization --- dental caries --- molar intrusion --- orthodontic treatment --- temporomandibular disorder --- occlusal splint --- centric relation --- bracket debonding --- dental enamel --- scanning electron microscopy --- orthodontics --- methacrylate monomer --- heat polymerization --- mechanical properties --- resin infiltration --- two-step adhesive system --- universal adhesive-derived primer --- adhesive layer thickness --- enamel bond durability --- orthodontic screw --- mini-implant --- pre-drilling --- heat production --- temperature --- irrigation --- cooled irrigation --- safety --- bone drilling --- orthodontic adhesive paste --- functional monomer --- pre-etched area --- chewing exercise --- masticatory function --- masticatory pattern --- open bite --- TADs --- cephalometric analysis --- treatment option criteria --- ROC analysis --- orthodontic retainer --- oral hygiene --- gingival recession --- patient compliance --- n/a
Choose an application
With advances in dental materials and their clinical applications, as well as innovations in computer technology, dental treatment is constantly evolving. In particular, adhesion technology to the tooth surface, implant treatments, and the application of CAD/CAM technology are very interesting topics for clinical dentists. As a bonding technique, the influence of the pre-etched area of the tooth surface on the adhesive strength can be reduced by the new application of a functional monomer. Additionally, the effect of an advanced adhesive system as a universal adhesive-derived primer, when compared with the two-step adhesive, is helpful for updating the applications of new materials. Dental implants are one of the most interesting dental treatments. PEEK (polyetheretherketone) has recently been reported as a further innovation in polymer implant materials, although it has not yet met the requirements to be a biomechanical requirement. In the placement of mini-screws used in orthodontic treatments, micro-cracks caused by overtorquing in thick and hard bone, and the consequent heat production, can reduce the success rate. Computer-aided design/computer-aided manufacturing (CAD/CAM) techniques are becoming increasingly popular. Since complete dentures can be produced using an additive (3D printing) or subtractive (milling) process, CAD/CAM techniques for denture fabrication have many clinical and laboratory advantages. Innovative and convenient dental material technology will be more and more expected in the future. This book has limited findings, but we hope that your clinical capability will be integrated and upgraded.
Information technology industries --- Computer science --- denture base --- complete denture --- acrylic resin --- CAD-CAM --- milling resin --- eye-tracking --- aesthetics --- golden ratio --- forensics --- caries model --- Streptococcus mutans --- demineralization --- dental caries --- molar intrusion --- orthodontic treatment --- temporomandibular disorder --- occlusal splint --- centric relation --- bracket debonding --- dental enamel --- scanning electron microscopy --- orthodontics --- methacrylate monomer --- heat polymerization --- mechanical properties --- resin infiltration --- two-step adhesive system --- universal adhesive-derived primer --- adhesive layer thickness --- enamel bond durability --- orthodontic screw --- mini-implant --- pre-drilling --- heat production --- temperature --- irrigation --- cooled irrigation --- safety --- bone drilling --- orthodontic adhesive paste --- functional monomer --- pre-etched area --- chewing exercise --- masticatory function --- masticatory pattern --- open bite --- TADs --- cephalometric analysis --- treatment option criteria --- ROC analysis --- orthodontic retainer --- oral hygiene --- gingival recession --- patient compliance
Choose an application
Various types of metallic and composite structures are used in modern engineering practice. For aerospace, car industry, and civil engineering applications, the most important are thin-walled structures made of di erent types of metallic alloys, brous composites, laminates, and multifunctional materials with a more complicated geometry of reinforcement including nanoparticles or nano bres. The current applications in modern engineering require analysis of structures of various properties, shapes, and sizes (e.g., aircraft wings) including structural hybrid joints, subjected to di erent types of loadings, including quasi-static, dynamic, cyclic, thermal, impact, penetration, etc.The advanced metallic and composite structures should satisfy multiple structural functions during operating conditions. Structural functions include mechanical properties such as strength, sti ness, damage resistance, fracture toughness, and damping. Non-structural functions include electrical and thermal conductivities, sensing, actuation, energy harvesting, self-healing capability, electromagnetic shielding, etc.The aim of this SI is to understand the basic principles of damage growth and fracture processes in advanced metallic and composite structures that also include structural joints. Presently, it is widely recognized that important macroscopic properties, such as macroscopic sti ness and strength, are governed by processes that occur at one to several scales below the level of observation. A thorough understanding of how these processes influence the reduction of sti ffness and strength forms the key to the design of improved innovative structural elements and the analysis of existing ones.
Technology: general issues --- steel–concrete composite bridge --- I-shaped beam --- concrete creep --- temperature --- prediction --- experiment --- through-beam joint --- concrete filled steel tube (CFST) columns --- reinforced concrete (RC) --- axial compressive behaviour --- steel mesh --- local compression --- confined concrete --- height factor --- curved steel–concrete composite box beam --- two-node finite beam element with 26 DOFs --- long-term behavior --- age-adjusted effective modulus method --- C-section --- TH-section --- distortional mode --- medium length --- interactive buckling --- compression --- Koiter’s theory --- FEM --- dynamic pulse buckling --- composite stanchion --- FE analysis --- nonlinear analysis --- crashworthiness --- modulus of elasticity --- pine wood --- wood defects --- knots --- laboratory tests --- beams --- glued laminated timber --- ceramic-matrix composites (CMCs) --- minicomposite --- tensile --- damage --- fracture --- timber --- natural composite --- Kolsky method --- deformation diagrams --- wood species --- energy absorption --- wood model --- verification --- nonlinear stability --- square plate --- shear forces --- components of transverse forces in bending --- membrane components of transverse forces --- 4 methods (CPT, FSDT, S-FSDT, FEM) --- connection --- test --- bolt --- steel plate --- moisture content --- failure --- AlCrN --- arc current --- structure --- hardness --- adhesion --- wear --- turbine jet engine --- material tests --- ember-resistant alloys --- wood --- cohesive law --- digital image correlation --- fracture mechanics --- mixed mode I+II loading --- dual adhesive --- single lap joints --- numerical modeling --- artificial neural networks --- sandwich panels with corrugated channel core --- 3D-printed sandwich --- bending response --- mechanism maps --- geometrical optimization --- dislocation–boundary interaction --- dislocation–interface interaction --- deformation twin-boundary interaction --- size effect --- boundary structure --- boundary strengthening --- characterization techniques --- adhesive joint --- adhesive bond strength --- adhesive layer thickness
Choose an application
Various types of metallic and composite structures are used in modern engineering practice. For aerospace, car industry, and civil engineering applications, the most important are thin-walled structures made of di erent types of metallic alloys, brous composites, laminates, and multifunctional materials with a more complicated geometry of reinforcement including nanoparticles or nano bres. The current applications in modern engineering require analysis of structures of various properties, shapes, and sizes (e.g., aircraft wings) including structural hybrid joints, subjected to di erent types of loadings, including quasi-static, dynamic, cyclic, thermal, impact, penetration, etc.The advanced metallic and composite structures should satisfy multiple structural functions during operating conditions. Structural functions include mechanical properties such as strength, sti ness, damage resistance, fracture toughness, and damping. Non-structural functions include electrical and thermal conductivities, sensing, actuation, energy harvesting, self-healing capability, electromagnetic shielding, etc.The aim of this SI is to understand the basic principles of damage growth and fracture processes in advanced metallic and composite structures that also include structural joints. Presently, it is widely recognized that important macroscopic properties, such as macroscopic sti ness and strength, are governed by processes that occur at one to several scales below the level of observation. A thorough understanding of how these processes influence the reduction of sti ffness and strength forms the key to the design of improved innovative structural elements and the analysis of existing ones.
steel–concrete composite bridge --- I-shaped beam --- concrete creep --- temperature --- prediction --- experiment --- through-beam joint --- concrete filled steel tube (CFST) columns --- reinforced concrete (RC) --- axial compressive behaviour --- steel mesh --- local compression --- confined concrete --- height factor --- curved steel–concrete composite box beam --- two-node finite beam element with 26 DOFs --- long-term behavior --- age-adjusted effective modulus method --- C-section --- TH-section --- distortional mode --- medium length --- interactive buckling --- compression --- Koiter’s theory --- FEM --- dynamic pulse buckling --- composite stanchion --- FE analysis --- nonlinear analysis --- crashworthiness --- modulus of elasticity --- pine wood --- wood defects --- knots --- laboratory tests --- beams --- glued laminated timber --- ceramic-matrix composites (CMCs) --- minicomposite --- tensile --- damage --- fracture --- timber --- natural composite --- Kolsky method --- deformation diagrams --- wood species --- energy absorption --- wood model --- verification --- nonlinear stability --- square plate --- shear forces --- components of transverse forces in bending --- membrane components of transverse forces --- 4 methods (CPT, FSDT, S-FSDT, FEM) --- connection --- test --- bolt --- steel plate --- moisture content --- failure --- AlCrN --- arc current --- structure --- hardness --- adhesion --- wear --- turbine jet engine --- material tests --- ember-resistant alloys --- wood --- cohesive law --- digital image correlation --- fracture mechanics --- mixed mode I+II loading --- dual adhesive --- single lap joints --- numerical modeling --- artificial neural networks --- sandwich panels with corrugated channel core --- 3D-printed sandwich --- bending response --- mechanism maps --- geometrical optimization --- dislocation–boundary interaction --- dislocation–interface interaction --- deformation twin-boundary interaction --- size effect --- boundary structure --- boundary strengthening --- characterization techniques --- adhesive joint --- adhesive bond strength --- adhesive layer thickness
Choose an application
Various types of metallic and composite structures are used in modern engineering practice. For aerospace, car industry, and civil engineering applications, the most important are thin-walled structures made of di erent types of metallic alloys, brous composites, laminates, and multifunctional materials with a more complicated geometry of reinforcement including nanoparticles or nano bres. The current applications in modern engineering require analysis of structures of various properties, shapes, and sizes (e.g., aircraft wings) including structural hybrid joints, subjected to di erent types of loadings, including quasi-static, dynamic, cyclic, thermal, impact, penetration, etc.The advanced metallic and composite structures should satisfy multiple structural functions during operating conditions. Structural functions include mechanical properties such as strength, sti ness, damage resistance, fracture toughness, and damping. Non-structural functions include electrical and thermal conductivities, sensing, actuation, energy harvesting, self-healing capability, electromagnetic shielding, etc.The aim of this SI is to understand the basic principles of damage growth and fracture processes in advanced metallic and composite structures that also include structural joints. Presently, it is widely recognized that important macroscopic properties, such as macroscopic sti ness and strength, are governed by processes that occur at one to several scales below the level of observation. A thorough understanding of how these processes influence the reduction of sti ffness and strength forms the key to the design of improved innovative structural elements and the analysis of existing ones.
Technology: general issues --- steel–concrete composite bridge --- I-shaped beam --- concrete creep --- temperature --- prediction --- experiment --- through-beam joint --- concrete filled steel tube (CFST) columns --- reinforced concrete (RC) --- axial compressive behaviour --- steel mesh --- local compression --- confined concrete --- height factor --- curved steel–concrete composite box beam --- two-node finite beam element with 26 DOFs --- long-term behavior --- age-adjusted effective modulus method --- C-section --- TH-section --- distortional mode --- medium length --- interactive buckling --- compression --- Koiter’s theory --- FEM --- dynamic pulse buckling --- composite stanchion --- FE analysis --- nonlinear analysis --- crashworthiness --- modulus of elasticity --- pine wood --- wood defects --- knots --- laboratory tests --- beams --- glued laminated timber --- ceramic-matrix composites (CMCs) --- minicomposite --- tensile --- damage --- fracture --- timber --- natural composite --- Kolsky method --- deformation diagrams --- wood species --- energy absorption --- wood model --- verification --- nonlinear stability --- square plate --- shear forces --- components of transverse forces in bending --- membrane components of transverse forces --- 4 methods (CPT, FSDT, S-FSDT, FEM) --- connection --- test --- bolt --- steel plate --- moisture content --- failure --- AlCrN --- arc current --- structure --- hardness --- adhesion --- wear --- turbine jet engine --- material tests --- ember-resistant alloys --- wood --- cohesive law --- digital image correlation --- fracture mechanics --- mixed mode I+II loading --- dual adhesive --- single lap joints --- numerical modeling --- artificial neural networks --- sandwich panels with corrugated channel core --- 3D-printed sandwich --- bending response --- mechanism maps --- geometrical optimization --- dislocation–boundary interaction --- dislocation–interface interaction --- deformation twin-boundary interaction --- size effect --- boundary structure --- boundary strengthening --- characterization techniques --- adhesive joint --- adhesive bond strength --- adhesive layer thickness
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