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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 --- 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

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Recent advances in the fabrication techniques have enabled the production of different types of polymer sensors and actuators that can be utilized in a wide range of applications, such as soft robotics, biomedical, smart textiles and energy harvesting. Functional polymers possess dynamic physical and chemical properties, which make them suitable candidates for sensing and actuating tasks in response to external stimuli, such as radiation, temperature, chemical reaction, external force, magnetic and electric fields. This book focuses on the recent advancements in the modeling and analysis of functional polymer systems.

History of engineering & technology --- polymer gel --- colloidal crystals --- optical film --- pH sensor --- graphene oxide --- silver nanowires --- ionic electroactive polymer --- poly(3,4-ethylenedioxythiophene)–poly(styrenesulfonate) (PEDOT:PSS) --- 4-(1,1,3,3-Tetramethylbutyl)phenyl-polyethylene glycol --- IIECMS --- MWCNT-CDC fibers --- PPy/DBS linear films --- uncertainty measurements --- electrostrictive properties --- actuators --- structural β-phase --- dielectric properties --- P(VDF-HFP) nanofibers --- electrospinning --- thermal compression --- hydrogels --- 3D printing --- tough --- sensor --- multi-parameter perturbation method --- piezoelectric polymers --- experimental verification --- cantilever beam --- force–electric coupling characteristics --- 4D printing --- metastructure --- shape-memory polymers --- wave propagation --- finite element method --- bandgap --- polymer composites --- microelectromechanical system (MEMS) --- electromagnetic (EM) actuator --- magnetic membrane --- microfluidic --- biomedical --- dynamic hydrogels --- tannic acid --- chitin nanofibers --- starch --- self-healing --- self-recovery --- functional polymers --- sensors

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

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.

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