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Ceramics --- Fracture --- Congresses --- CRACKS --- MECHANICAL PROPERTIES --- BRITTLE FRACTURE --- Monograph

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This book offers a collection of 17 scientific papers about the computational modeling of fracture. Some of the manuscripts propose new computational methods and/or how to improve existing cutting edge methods for fracture. These contributions can be classified into two categories: 1. Methods which treat the crack as strong discontinuity such as peridynamics, scaled boundary elements or specific versions of the smoothed finite element methods applied to fracture and 2. Continuous approaches to fracture based on, for instance, phase field models or continuum damage mechanics. On the other hand, the book also offers a wide range of applications where state-of-the-art techniques are employed to solve challenging engineering problems such as fractures in rock, glass, concrete. Also, larger systems such as fracture in subway stations due to fire, arch dams, or concrete decks are studied.

Brittle Fracture --- n/a --- microstructure --- fatigue crack growth --- fracture process zone (FPZ) --- crack shape change --- fracture network modeling --- Mohr-Coulomb --- fracture --- SBFEM --- topological insulator --- fatigue --- progressive collapse analysis --- Phase-field model --- loss of key components --- concrete creep --- compressive stress --- rail squats --- cracks --- force transfer --- rolling contact --- damage-plasticity model --- implicit gradient-enhancement --- extended scaled boundary finite element method (X-SBFEM) --- three-parameter model --- LEFM --- overall stability --- EPB shield machine --- metallic glass matrix composite --- phase field --- reinforced concrete core tube --- bulk damage --- ductility --- thermomechanical analysis --- incompatible approximation --- moderate fire --- finite element simulations --- shear failure --- FSDT --- gradient-enhanced model --- prestressing stress --- self-healing --- peridynamics --- damage-healing mechanics --- stress intensity factors --- damage --- dam stress zones --- shear band --- rock fracture --- random fracture --- surface crack --- plate --- steel reinforced concrete frame --- super healing --- brittle material --- geometric phase --- FE analysis --- grouting --- rock --- elastoplastic behavior --- parameters calibration --- screened-Poisson model --- anisotropic --- numerical simulation --- Discontinuous Galerkin --- brittle fracture --- XFEM/GFEM --- topological photonic crystal --- photonic orbital angular momentum --- conditioned sandy pebble --- yielding region --- finite element analysis --- fluid–structure interaction --- cracking risk --- Mindlin --- ABAQUS UEL --- particle element model --- HSDT --- cell-based smoothed-finite element method (CS-FEM) --- the Xulong arch dam --- fluid-structure interaction

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Micro- and nanomanufacturing technologies have been researched and developed in the industrial environment with the goal of supporting product miniaturization and the integration of new functionalities. The technological development of new materials and processing methods needs to be supported by predictive models which can simulate the interactions between materials, process states, and product properties. In comparison with the conventional manufacturing scale, micro- and nanoscale technologies require the study of different mechanical, thermal, and fluid dynamics, phenomena which need to be assessed and modeled.This Special Issue is dedicated to advances in the modeling of micro- and nanomanufacturing processes. The development of new models, validation of state-of-the-art modeling strategies, and approaches to material model calibration are presented. The goal is to provide state-of-the-art examples of the use of modeling and simulation in micro- and nanomanufacturing processes, promoting the diffusion and development of these technologies.

Technology: general issues --- History of engineering & technology --- modular microfluidic system --- 3D printing --- gel microspheres --- laser-induced periodical surface structures --- micro-injection molding --- replication --- surface wettability --- micro-groove --- electrochemical machining --- porous cathode --- conductive mask --- machining localization --- dimensional uniformity --- nanogrinding --- abrasive grains --- rake angle --- spacing --- grinding forces --- grinding temperature --- chip formation --- subsurface damage --- micro injection molding --- additive manufacturing --- stereolithography --- K9 glass --- mathematical model --- grinding force --- brittle fracture --- ductile–brittle transition --- active grains number --- lithography simulation --- microelectromechanical system --- waveguide method --- microstructure --- radial ultrasonic rolling electrochemical micromachining (RUR-EMM) --- material removal amount --- surface roughness --- response surface methodology (RSM) --- turning --- minimum chip thickness --- micromachining --- femtosecond micromachining --- burst processing --- intraocular lens --- hydrophilic acrylic --- polishing --- laser assisted turning --- tungsten carbide --- diamond turning --- finite element analysis --- prostheses --- ITAP --- micro topology --- ANSYS --- MATLAB --- additive manufacture --- n/a --- ductile-brittle transition

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This book was proposed and organized as a means to present recent developments in the field of nondestructive testing of materials in civil engineering. For this reason, the articles highlighted in this editorial relate to different aspects of nondestructive testing of different materials in civil engineering—from building materials to building structures. The current trend in the development of nondestructive testing of materials in civil engineering is mainly concerned with the detection of flaws and defects in concrete elements and structures, and acoustic methods predominate in this field. As in medicine, the trend is towards designing test equipment that allows one to obtain a picture of the inside of the tested element and materials. From this point of view, interesting results with significance for building practices have been obtained

microstructure --- acoustic emission AE --- rebound hammer --- service life of a structure --- horizontal casting --- precipitation --- natural frequency --- reinforced concrete chimney --- diagnostic --- moisture safety --- adhesion assessment --- gantry crane --- stress wave --- materials research --- acoustic methods --- SEM-EDS analysis --- SilverSchmidt --- reinforced concrete grandstand stadium --- concrete strength --- autoclaved aerated concrete (AAC) --- concrete elements --- reinforced concrete tanks --- degree of degradation --- fatigue tests --- X-ray micro-computed tomography --- GPR method --- defects --- singular value truncation --- ultrasonic tomography --- cement-based composites --- SEM --- moisture of AAC --- sulphate corrosion --- damage --- strengthening --- masonry structures --- eddy-current method --- non-destructive evaluation --- non-destructive testing --- NDT methods --- Structural Health Monitoring --- mercury intrusion porosimetry --- temperature --- vibration analysis --- cesium --- rebar location --- nanoindentation --- monitoring of structures --- RMF technique --- machine learning --- lead --- viscoelastic parameters --- structural tuning --- diagnostics --- resistance measurement --- thermal contrast --- non-destructive method --- destruction process --- asphalt mixtures --- solid-state NMR spectroscopy --- quasi brittle cement composites --- fibre-cement boards --- adhesive joints --- compressive strength --- nondestructive testing --- defect detection --- location of inclusions --- active thermography --- concrete strength prediction --- concrete mix design --- building materials --- micro-computed tomography --- adsorption --- timber structures --- scanning laser vibrometry --- durability --- ultrasonic wave --- surface complexation --- artificial neural networks --- civil engineering --- ultrasonic testing --- ultrasound tests --- acoustic emission --- cellulose fibre cement boards --- concrete --- excitation frequency --- data mining --- crowd-induced excitation --- ultrasound measurements --- wood moisture sensing --- acoustic spectrum --- thermovision --- corrosion processes --- four point bending beam --- spun concrete --- structural damage --- X-ray computed tomography --- waste brick dust --- concrete slabs and floorings --- mathematical morphology --- Burgers model --- pattern recognition --- brittle fracture --- data noise --- drilling resistance --- damage detection --- fiber cement boards --- thermography --- non-destructive methods --- concrete corrosion --- ultrasound --- Lamb waves --- deconvolution --- ultrasonic tests --- creep test --- shape and size of specimen --- building partition --- multiple feedbacks