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Stimuli-responsive polymer systems can be defined as functional materials that show physical or chemical property changes in response to external stimuli such as temperature, radiation, chemical agents, pH, mechanical stress, and electric and magnetic fields. Recent developments in manufacturing techniques have facilitated the production of a wide range of stimuli-responsive polymer systems, such as micro- and nanoscale structures, with potential applications in soft sensors and actuators, smart textiles, soft robots, and artificial muscles. This book brings together the recent progress in manufacturing techniques, with particular emphasis on 3D and 4D printing and applications of stimuli-responsive polymer systems in biomedicine and soft robotics.
3D print --- modeling --- hindered phenol --- permeability --- experiments --- interpenetrated polymers --- acrylic rubber --- soft robotic actuators --- silk fibroin --- shape-memory polymer --- biomedical applications --- 4D printing --- stimuli-responsive materials --- relative humidity --- shape memory polymer --- bioink --- climatic chamber --- diffraction gratings --- soft actuator --- FEM --- hydrogen bonding --- self-morphing --- gelatin --- stimuli-responsive polymer --- soft robot --- 3D printing --- properties
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"Smart Materials in Additive Manufacturing, Volume 1 provides readers with an overview of the current smart materials widely in use and the techniques for additively manufacturing them. It demonstrates the principles developed for 4D printing in a way that is useful for students, early career researchers, and professionals. Topics covered include modeling and fabrication of 4D printed materials such as dielectric elastomer soft robots, low-voltage electroactive polymers, and stimuli-responsive hydrogels. 4D printing of light-responsive structures, gels and soft materials, and natural fiber composites are also discussed, as is origami-inspired 4D printing, 4D microprinting, and reversible 4D printing. 4D bioprinting and related biomedical applications are outlined as well as functionalized 4D printed sensor systems."--
Smart materials. --- Smart structures. --- Additive manufacturing. --- Adaptive materials --- Intelligent materials --- Sense-able materials --- Materials --- Adaptive structures --- Intelligent structures --- Structural control (Engineering) --- AM (Additive manufacturing) --- Manufacturing processes --- Three-dimensional printing. --- Smart Materials --- Printing, Three-Dimensional --- Bioprinting
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"Smart Materials in Additive Manufacturing, Volume 2 covers the mechanics, modeling, and applications of the technology and the materials produced by it. It approaches the topic from an engineering design perspective with cutting-edge modeling techniques and real-world applications and case studies highlighted throughout. The book demonstrates 4D printing techniques for electro-induced shape memory polymers, pneumatic soft actuators, textiles, and more. Modeling techniques with ABAQUS and machine learning are outlined, as are manufacturing techniques for highly elastic skin, tunable RF and wireless structures and modules, and 4D printed structures with tunable mechanical properties. Closed-loop control of 4D printed hydrogel soft robots, hierarchical motion of 4D printed structures using the temperature memory effect, multimaterials 4D printing using a grasshopper plugin, shape reversible 4D printing, and variable stiffness 4D printing are each discussed as well."--
Additive manufacturing. --- Smart materials. --- Adaptive materials --- Intelligent materials --- Sense-able materials --- Materials --- AM (Additive manufacturing) --- Manufacturing processes --- Smart structures. --- Three-dimensional printing. --- Smart Materials --- Printing, Three-Dimensional --- Bioprinting
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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.
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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Functional polymers show unique physical and chemical properties, which can manifest as dynamic responses to external stimuli such as radiation, temperature, chemical reaction, external force, and magnetic and electric fields. Recent advances in the fabrication techniques have enabled different types of polymer systems to be utilized in a wide range of potential applications in smart structures and systems, including structural health monitoring, anti‐vibration, and actuators. The progress in these integrated smart structures requires the implementation of finite element modelling using a multiphysics approach in various computational platforms. This book presents finite element methods applied in modeling of the smart structures and materials with particular emphasis on hydrogels, metamaterials, 3D-printed and anti-vibration constructs, and fibers.
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