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2D nanomaterials are a relatively populous and ever-expanding class of innovative materials with disruptive potential for different application contexts. Although for some of them, such as graphene, various possible implementations have already been explored in different application fields, others, (e.g., Mxenes), are still relatively at an infantile stage with regard to handling, stability, exploitation, processing and practical use in devices and structures with higher dimensionality.In any case, regardless of the specific nature of each of these materials, their degree of purity and structure (mono-layers/few-layers/multi-layers) and their level of maturity, they all share the same challenges since their onset, such as processing, patterning, transfer and integration in devices, allowing smart exploitation of their unique properties, incorporation in matrices of different nature for the synthesis of nano-composites, and so on.Accordingly, this book aims to showcase research papers and review articles outlining recent progress and innovative approaches for 2D nanomaterials synthesis and/or processing, preparatory to their assembly or integration into devices, microstructures, microsensors and composites for different application fields.

Technology: general issues --- graphene --- patterning --- Pt --- 2D materials --- chemical vapor deposition (CVD) --- naked-eye 3D --- microstructure --- flexible --- film --- fabrication --- biodevices --- integration --- miniaturized devices --- Si3N4 --- lubrication --- friction --- temperature rise --- photo-assisted etching --- porous silicon --- illumination --- doping level --- total current --- reflectance --- fano resonance --- plasmonic sensor --- Au/Pd --- SiC --- nanomorphology --- coalescence --- percolation --- scanning electron microscopy --- inkjet printing --- nanoparticle --- metal-organic decomposition --- silver thin film --- adhesion strength --- electrical resistivity --- monolayer MoS2 --- 10-nm nanogap --- localized surface plasmon resonance --- photoluminescence --- n/a

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Machining remains one of the most important manufacturing processes in the metalworking industry. Studies on this process have investigated the machinability of different materials, the behaviour of tools, chip formation, surface integrity, forces involved, and its economic and environmental sustainability. New materials are constantly being developed, and machining research needs to closely follow these developments. This book examines recent research in the machining field, covering several aspects and presenting very interesting developments in this area of knowledge.

Technology: general issues --- magnesium alloy --- UNS M11917 --- AZ91D --- hole repair --- surface roughness --- dry drilling --- re-drilling --- thin plates --- thin-wall --- machining --- aluminium --- cutting forces --- roughness --- dry --- carbide tool --- Haynes 282 --- finishing turning --- UNS A97075 --- dry turning --- surface integrity --- straightness --- parallelism --- roundness --- concentricity --- circular run-out --- total run-out --- cylindricity --- tool edge preparation --- segmented chip --- machining simulation --- burr --- optimization --- turning process --- turning tools --- solid tools --- cemented carbide --- coated tools --- coated cemented carbide --- Physical Vapor Deposition (PVD) --- Chemical Vapor Deposition (CVD) --- multilayered coatings --- nanolayered coatings --- wear mechanism --- tool life --- minimum quantity Lubricant (MQL) --- cutting energy --- tool damage --- liquid nitrogen --- carbon dioxide snow --- vibrations --- part quality --- flexible vacuum fixture --- AA2024 floor milling --- chip segmentation --- damage modeling --- dynamic strain aging --- stainless steel --- Ca treatment --- machinability --- turning --- chip breakability --- weight distribution --- non-metallic inclusions --- AWJM (abrasive water jet machining) --- CFRTP (carbon fiber-reinforced thermoplastics) --- hybrid structure --- surface quality --- Ra --- Rz --- C/TPU (carbon/thermoplastic polyurethane) --- milling --- tool coating --- TiAlN --- TiAlN-based coatings --- multilayer --- nanolayer --- wear mechanisms --- n/a

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Machining remains one of the most important manufacturing processes in the metalworking industry. Studies on this process have investigated the machinability of different materials, the behaviour of tools, chip formation, surface integrity, forces involved, and its economic and environmental sustainability. New materials are constantly being developed, and machining research needs to closely follow these developments. This book examines recent research in the machining field, covering several aspects and presenting very interesting developments in this area of knowledge.

Technology: general issues --- magnesium alloy --- UNS M11917 --- AZ91D --- hole repair --- surface roughness --- dry drilling --- re-drilling --- thin plates --- thin-wall --- machining --- aluminium --- cutting forces --- roughness --- dry --- carbide tool --- Haynes 282 --- finishing turning --- UNS A97075 --- dry turning --- surface integrity --- straightness --- parallelism --- roundness --- concentricity --- circular run-out --- total run-out --- cylindricity --- tool edge preparation --- segmented chip --- machining simulation --- burr --- optimization --- turning process --- turning tools --- solid tools --- cemented carbide --- coated tools --- coated cemented carbide --- Physical Vapor Deposition (PVD) --- Chemical Vapor Deposition (CVD) --- multilayered coatings --- nanolayered coatings --- wear mechanism --- tool life --- minimum quantity Lubricant (MQL) --- cutting energy --- tool damage --- liquid nitrogen --- carbon dioxide snow --- vibrations --- part quality --- flexible vacuum fixture --- AA2024 floor milling --- chip segmentation --- damage modeling --- dynamic strain aging --- stainless steel --- Ca treatment --- machinability --- turning --- chip breakability --- weight distribution --- non-metallic inclusions --- AWJM (abrasive water jet machining) --- CFRTP (carbon fiber-reinforced thermoplastics) --- hybrid structure --- surface quality --- Ra --- Rz --- C/TPU (carbon/thermoplastic polyurethane) --- milling --- tool coating --- TiAlN --- TiAlN-based coatings --- multilayer --- nanolayer --- wear mechanisms --- magnesium alloy --- UNS M11917 --- AZ91D --- hole repair --- surface roughness --- dry drilling --- re-drilling --- thin plates --- thin-wall --- machining --- aluminium --- cutting forces --- roughness --- dry --- carbide tool --- Haynes 282 --- finishing turning --- UNS A97075 --- dry turning --- surface integrity --- straightness --- parallelism --- roundness --- concentricity --- circular run-out --- total run-out --- cylindricity --- tool edge preparation --- segmented chip --- machining simulation --- burr --- optimization --- turning process --- turning tools --- solid tools --- cemented carbide --- coated tools --- coated cemented carbide --- Physical Vapor Deposition (PVD) --- Chemical Vapor Deposition (CVD) --- multilayered coatings --- nanolayered coatings --- wear mechanism --- tool life --- minimum quantity Lubricant (MQL) --- cutting energy --- tool damage --- liquid nitrogen --- carbon dioxide snow --- vibrations --- part quality --- flexible vacuum fixture --- AA2024 floor milling --- chip segmentation --- damage modeling --- dynamic strain aging --- stainless steel --- Ca treatment --- machinability --- turning --- chip breakability --- weight distribution --- non-metallic inclusions --- AWJM (abrasive water jet machining) --- CFRTP (carbon fiber-reinforced thermoplastics) --- hybrid structure --- surface quality --- Ra --- Rz --- C/TPU (carbon/thermoplastic polyurethane) --- milling --- tool coating --- TiAlN --- TiAlN-based coatings --- multilayer --- nanolayer --- wear mechanisms

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The innovative coating and surface hardening technologies developed in recent years allow us to obtain practically any physical–mechanical or crystal–chemical complex properties of the metalworking tool surface layer. Today, the scientific approach to improving the operational characteristics of the tool surface layers produced from traditional tools industrial materials is a highly costly and long-lasting process. Different technological techniques, such as coatings (physical and chemical methods), surface hardening and alloying (chemical-thermal treatment, implantation), a combination of the listed methods, and other solutions are used for this. This edition aims to provide a review of the current state of the research and developments in the field of coatings and surface hardening technologies for cutting and die tools that can ensure a substantial increase of the work resource and reliability of the tool, an increase in productivity of machining, accuracy, and quality of the machined products, reduction in the material capacity of the production, and other important manufacturing factors. In doing so, the main emphasis should be on the results of the engineering works that have had a prosperous approbation in a laboratory or real manufacturing conditions.

Technology: general issues --- hierarchical structure --- multilayer PVD coating --- stochastic process --- convection and diffusion --- reactive magnetron sputtering --- argon --- nitrogen and ethylene --- TaSi2 --- Ta3B4 and ZrB2 --- SHS and hot pressing --- composition and structure --- hardness and elastic modulus --- friction coefficient and wear resistance --- oxidation resistance --- diamond-like coatings --- nitride sublayer --- index of plasticity --- adhesive bond strength --- end mills --- hard alloy --- wear resistance --- milling of aluminum alloys --- milling of structural steels --- surface quality --- modeling --- carbon flux --- low-pressure vacuum carburizing --- medium-high alloy steel --- nanolayered PVD coating --- microdroplets --- crack formation --- tool wear --- nanolayered coating --- microparticles --- monocrystalline --- high-pressure, high-temperature (HPHT) diamond --- chemical vapor deposition (CVD) diamond --- high-fluence ion irradiation --- Ar+ --- C+ --- SEM --- AFM --- Raman spectra --- electrical conductivity --- AlCr-based --- CrAl-based --- (AlCrX)N --- (Al1−xCrx)2O3 --- arc --- HiPIMS --- nanolayers --- nanocomposite --- structure --- properties --- roughness --- coatings --- finish turning --- PCBN --- tempered steel --- micro cutters --- cutting edges --- wear-resistance --- coating deposition --- adhesion --- plasma --- ions --- charge exchange collisions --- fast gas atoms --- etching --- sharpening --- diamond-like carbon coating --- high-speed milling --- nickel alloy --- SiAlON --- spark plasma sintering --- adaptive coating --- adaptive material --- composite powder HSS --- cutting tool --- secondary structures --- surface layer --- thermal-force loads --- hierarchical structure --- multilayer PVD coating --- stochastic process --- convection and diffusion --- reactive magnetron sputtering --- argon --- nitrogen and ethylene --- TaSi2 --- Ta3B4 and ZrB2 --- SHS and hot pressing --- composition and structure --- hardness and elastic modulus --- friction coefficient and wear resistance --- oxidation resistance --- diamond-like coatings --- nitride sublayer --- index of plasticity --- adhesive bond strength --- end mills --- hard alloy --- wear resistance --- milling of aluminum alloys --- milling of structural steels --- surface quality --- modeling --- carbon flux --- low-pressure vacuum carburizing --- medium-high alloy steel --- nanolayered PVD coating --- microdroplets --- crack formation --- tool wear --- nanolayered coating --- microparticles --- monocrystalline --- high-pressure, high-temperature (HPHT) diamond --- chemical vapor deposition (CVD) diamond --- high-fluence ion irradiation --- Ar+ --- C+ --- SEM --- AFM --- Raman spectra --- electrical conductivity --- AlCr-based --- CrAl-based --- (AlCrX)N --- (Al1−xCrx)2O3 --- arc --- HiPIMS --- nanolayers --- nanocomposite --- structure --- properties --- roughness --- coatings --- finish turning --- PCBN --- tempered steel --- micro cutters --- cutting edges --- wear-resistance --- coating deposition --- adhesion --- plasma --- ions --- charge exchange collisions --- fast gas atoms --- etching --- sharpening --- diamond-like carbon coating --- high-speed milling --- nickel alloy --- SiAlON --- spark plasma sintering --- adaptive coating --- adaptive material --- composite powder HSS --- cutting tool --- secondary structures --- surface layer --- thermal-force loads

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

The innovative coating and surface hardening technologies developed in recent years allow us to obtain practically any physical–mechanical or crystal–chemical complex properties of the metalworking tool surface layer. Today, the scientific approach to improving the operational characteristics of the tool surface layers produced from traditional tools industrial materials is a highly costly and long-lasting process. Different technological techniques, such as coatings (physical and chemical methods), surface hardening and alloying (chemical-thermal treatment, implantation), a combination of the listed methods, and other solutions are used for this. This edition aims to provide a review of the current state of the research and developments in the field of coatings and surface hardening technologies for cutting and die tools that can ensure a substantial increase of the work resource and reliability of the tool, an increase in productivity of machining, accuracy, and quality of the machined products, reduction in the material capacity of the production, and other important manufacturing factors. In doing so, the main emphasis should be on the results of the engineering works that have had a prosperous approbation in a laboratory or real manufacturing conditions.

Technology: general issues --- hierarchical structure --- multilayer PVD coating --- stochastic process --- convection and diffusion --- reactive magnetron sputtering --- argon --- nitrogen and ethylene --- TaSi2 --- Ta3B4 and ZrB2 --- SHS and hot pressing --- composition and structure --- hardness and elastic modulus --- friction coefficient and wear resistance --- oxidation resistance --- diamond-like coatings --- nitride sublayer --- index of plasticity --- adhesive bond strength --- end mills --- hard alloy --- wear resistance --- milling of aluminum alloys --- milling of structural steels --- surface quality --- modeling --- carbon flux --- low-pressure vacuum carburizing --- medium-high alloy steel --- nanolayered PVD coating --- microdroplets --- crack formation --- tool wear --- nanolayered coating --- microparticles --- monocrystalline --- high-pressure, high-temperature (HPHT) diamond --- chemical vapor deposition (CVD) diamond --- high-fluence ion irradiation --- Ar+ --- C+ --- SEM --- AFM --- Raman spectra --- electrical conductivity --- AlCr-based --- CrAl-based --- (AlCrX)N --- (Al1−xCrx)2O3 --- arc --- HiPIMS --- nanolayers --- nanocomposite --- structure --- properties --- roughness --- coatings --- finish turning --- PCBN --- tempered steel --- micro cutters --- cutting edges --- wear-resistance --- coating deposition --- adhesion --- plasma --- ions --- charge exchange collisions --- fast gas atoms --- etching --- sharpening --- diamond-like carbon coating --- high-speed milling --- nickel alloy --- SiAlON --- spark plasma sintering --- adaptive coating --- adaptive material --- composite powder HSS --- cutting tool --- secondary structures --- surface layer --- thermal-force loads