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This dissertation face the subject of the study of mechanical properties between the joint of two materials taking into account the geometry gradient and the disorder which are implicitly present in nature

Bio-inspired suture interfaces --- Geometry gradients --- Disorder --- Mechanical behaviour --- Ingénierie, informatique & technologie > Ingénierie aérospatiale

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This Special Issue focuses on recycled materials to promote pavement sustainability. It covers the use of construction and demolition waste (reclaimed asphalt pavement, recycled concrete aggregate and glass) and industrial waste (plastic and slag). The application of recycled materials concerns bituminous mixtures, concrete mixtures, and non-traditional interlocking blocks or cobbles.

Technology: general issues --- History of engineering & technology --- Transport technology & trades --- LCA --- road pavement management --- RAP --- multi-recycling --- circular economy --- sustainability --- electric–electronic waste --- interlock floor --- mechanical resistance --- polymers recycling --- materials --- recycling --- plastics --- cobbles --- lightweight traffic --- pedestrian traffic --- concrete additive --- concrete mixture --- plastic waste --- HDPE --- plastic lamellar particles --- self-compacting concrete (SCC) --- high-performance concrete (HPC) --- recycled concrete aggregate (RCA) --- natural aggregate (NA) --- ageing --- bituminous mixture --- mechanical behaviour --- rejuvenator --- hydraulic mortars --- waste materials --- pozzolanic aggregates --- recycled glass --- marble slurry --- tin slag --- mortar --- compressive strength --- fine aggregate --- rough surfaced --- elongated --- concrete --- costs --- carbon footprint --- carbon price --- asphalt --- waste plastic --- visco-elastic properties --- Marshall stability --- rutting resistance --- environmental impact --- n/a --- electric-electronic waste

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This Special Issue focuses on recycled materials to promote pavement sustainability. It covers the use of construction and demolition waste (reclaimed asphalt pavement, recycled concrete aggregate and glass) and industrial waste (plastic and slag). The application of recycled materials concerns bituminous mixtures, concrete mixtures, and non-traditional interlocking blocks or cobbles.

Technology: general issues --- History of engineering & technology --- Transport technology & trades --- LCA --- road pavement management --- RAP --- multi-recycling --- circular economy --- sustainability --- electric-electronic waste --- interlock floor --- mechanical resistance --- polymers recycling --- materials --- recycling --- plastics --- cobbles --- lightweight traffic --- pedestrian traffic --- concrete additive --- concrete mixture --- plastic waste --- HDPE --- plastic lamellar particles --- self-compacting concrete (SCC) --- high-performance concrete (HPC) --- recycled concrete aggregate (RCA) --- natural aggregate (NA) --- ageing --- bituminous mixture --- mechanical behaviour --- rejuvenator --- hydraulic mortars --- waste materials --- pozzolanic aggregates --- recycled glass --- marble slurry --- tin slag --- mortar --- compressive strength --- fine aggregate --- rough surfaced --- elongated --- concrete --- costs --- carbon footprint --- carbon price --- asphalt --- waste plastic --- visco-elastic properties --- Marshall stability --- rutting resistance --- environmental impact --- LCA --- road pavement management --- RAP --- multi-recycling --- circular economy --- sustainability --- electric-electronic waste --- interlock floor --- mechanical resistance --- polymers recycling --- materials --- recycling --- plastics --- cobbles --- lightweight traffic --- pedestrian traffic --- concrete additive --- concrete mixture --- plastic waste --- HDPE --- plastic lamellar particles --- self-compacting concrete (SCC) --- high-performance concrete (HPC) --- recycled concrete aggregate (RCA) --- natural aggregate (NA) --- ageing --- bituminous mixture --- mechanical behaviour --- rejuvenator --- hydraulic mortars --- waste materials --- pozzolanic aggregates --- recycled glass --- marble slurry --- tin slag --- mortar --- compressive strength --- fine aggregate --- rough surfaced --- elongated --- concrete --- costs --- carbon footprint --- carbon price --- asphalt --- waste plastic --- visco-elastic properties --- Marshall stability --- rutting resistance --- environmental impact

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Bone tissue engineering aims to develop artificial bone substitutes that partially or totally restore the natural regeneration capability of bone tissue lost under circumstances of injury, significant defects, or diseases such as osteoporosis. In this context, biomaterials are the keystone of the methodology. Biomaterials for bone tissue engineering have evolved from biocompatible materials that mimic the physical and chemical environment of bone tissue to a new generation of materials that actively interacts with the physiological environment, accelerating bone tissue growth. Mathematical modelling and simulation are important tools in the overall methodology. This book presents an overview of the current investigations and recent contributions in the field of bone tissue engineering. It includes several successful examples of multidisciplinary collaboration in this transversal area of research. The book is intended for students, researchers, and professionals of a number of disciplines, such as engineering, mathematics, physics, chemistry, biomedicine, biology, and veterinary. The book is composed of an editorial section and 16 original research papers authored by leading researchers of this discipline from different laboratories across the world

bone morphogenesis proteins --- n/a --- finite element --- bone tissue engineering --- electrically active implants --- prediction marker --- vertebra --- direct current electric field --- loose sintering --- Lattice Boltzmann method --- Pelvis --- automatic segmentation --- MSCs --- additive manufacturing --- finite element method --- bioelectromagnetism --- optimization --- scaffold design --- cone beam computed tomography --- computational modelling --- bone regeneration --- oxygen delivery --- biomaterials --- bone tissue --- spark plasma sintering --- critical size defect --- musculoskeletal modelling --- resonance frequency analysis --- minipig --- numerical methods in bioengineering --- computational fluid dynamics --- maxillofacial --- osteoporosis --- sliding window --- osseointegration --- mass transfer --- substrate-mediated electrical stimulation --- Fixation design --- dental implants --- human dental pulp stem cells --- numerical results --- elastoplasticity --- bone tissue regeneration --- finite-element simulation --- 3D-printed implant --- selective laser melting --- Lagrangian scalar tracking --- cortical bone --- micromechanics --- trabeculae --- finite element modelling --- damage --- titanium --- powder metallurgy --- pelvis --- biomechanics --- computational mechanobiology --- culturing protocol --- bone adaptation --- stem cell --- Bone tumor --- trabecular bone score --- Xenografts --- triply periodic minimal surfaces --- computed tomography --- multiscale analysis --- cartilage --- digital image correlation --- osteo-differentiation --- wollastonite --- transport --- finite element analysis --- bone marrow --- fracture risk --- von Mises stress --- electric stimulation --- mechanical behaviour --- adipogenesis --- biomaterial applications --- computational mechanics --- Ti6Al4V scaffolds --- finite elements --- Otsu’s method --- 3D virtual surgical plan --- Otsu's method