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Bio-inspired Hybrid Carbon Nanotube Muscles.Hydro-responsive curling of the resurrection plant Selaginella lepidophyllaHydrogel Walkers with Electro-Driven Motility for Cargo Transport.Sequential self-folding of polymer sheetsPhotoactive Self-Shaping Hydrogels as Noncontact 3D Macro/Microscopic Photoprinting Platforms.4D Printing with Mechanically Robust, Thermally Actuating Hydrogels.Shape-shifting 3D protein microstructures with programmable directionality via quantitative nanoscale stiffness modulation.Microrobotic tentacles with spiral bending capability based on shape-engineered elastomeric microtubes.Honeycomb Actuators Inspired by the Unfolding of Ice Plant Seed Capsules.Recent developments and directions in printed nanomaterials.Biologically inspired dynamic material systems.Fabrication of Millimeter-Long Carbon Tubular Nanostructures Using the Self-Rolling Process Inherent in Elastic Protein Layers.Gels with sense: supramolecular materials that respond to heat, light and sound.Printing soft matter in three dimensions.Soft Actuators for Small-Scale Robotics.A self-regulating antimicrobial model based on the ion-exchange stimuli.Cooperative deformations of periodically patterned hydrogels.A Bioinspired Swimming and Walking Hydrogel Driven by Light-Controlled Local Density.Reprogrammable ultra-fast shape-transformation of macroporous composite hydrogel sheets.Stimuli-responsive microjets with reconfigurable shape.Harnessing Photochemical Shrinkage in Direct Laser Writing for Shape Morphing of Polymer Sheets.Remotely Triggered Locomotion of Hydrogel Mag-bots in Confined Spaces.Reversible Semicrystalline Polymer as Actuators Driven by Organic Solvent Vapor.Site-Specific Pre-Swelling-Directed Morphing Structures of Patterned Hydrogels.Self-powered hydrogels induced by ion transport.Synthesis of Anisotropic Hydrogels and Their Applications.An integrated design and fabrication strategy for entirely soft, autonomous robots.Fast-responsive hydrogel as an injectable pump for rapid on-demand fluidic flow control.Vapomechanically Responsive Motion of Microchannel-Programmed Actuators.Impermeable Robust Hydrogels via Hybrid Lamination.Topography-guided buckling of swollen polymer bilayer films into three-dimensional structures.Programmable shape transformation of elastic spherical domes.Bioprinting of 3D hydrogels.A simple strategy for in situ fabrication of a smart hydrogel microvalve within microchannels for thermostatic control.Spatial structuring of a supramolecular hydrogel by using a visible-light triggered catalyst.A Multiresponsive Anisotropic Hydrogel with Macroscopic 3D Complex DeformationsBioinspired Anisotropic Hydrogel Actuators with On-Off Switchable and Color-Tunable Fluorescence BehaviorsPhotothermally Triggered Shape-Adaptable 3D Flexible ElectronicsSensitively Humidity-Driven Actuator Based on Photopolymerizable PEG-DA FilmsMorphing in nature and beyond: a review of natural and synthetic shape-changing materials and mechanisms
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Q27312354-DA1AE947-4521-454F-B20B-63A169D003F8Q29542097-C2FABE72-EC40-4288-8DDB-3069E33304ECQ30662816-E9377888-929A-47D7-914C-842118BB1049Q30840599-5235C988-CC4B-4EEE-B30B-FEB4338E23ABQ33445355-A00F38E3-CF37-4910-AE0F-2A1467FEF257Q34471299-83F27CDC-8129-4C7D-83E1-FBED4D47F762Q35283397-BA46E738-5D2A-436E-946B-C04D590A4513Q35725303-931040C0-90F8-43FD-9E8B-70FCE6682FAEQ36180213-BBDAEF19-1B41-4855-B111-3298740A0F31Q38264676-0B7087E1-7D03-4814-BD2B-4CABAC5D8704Q38316291-E54CF282-550C-4DD2-8F06-BFB420748C3DQ38669559-58DE265A-810B-403A-8A42-1616B4B9D344Q38973655-E7640ED3-0525-46DE-ABCA-49974F5E3CD0Q39038668-29029C04-2282-4095-AF4D-50A171C99F39Q39062099-8DAD7021-3C51-4AFB-A2F7-442994A2D81BQ41115873-1C92A6DC-DD1D-466B-B4FF-72594FCA7431Q41723365-8C527727-0609-4248-9C46-BE0946A96271Q41851983-65C89B16-A6E0-421A-A914-328970074C6DQ42378278-C4CC97AC-D02C-45A5-B1B5-87E35388320CQ43054701-8B1D8081-7CDE-43A7-84D3-A091A302941CQ46161561-5A6C5B04-3AB7-48C5-AD72-7C925AA0DF1BQ47114027-A1875B11-959A-47C6-9F98-E5322D66835EQ47190791-C6DFB50A-47D2-4675-ADEC-875B11189E8FQ47379064-CDBC7F09-B76D-4602-9261-0B4BB69D7F82Q47396377-4C6122E3-79CA-4043-A8A7-B4622E75AB7CQ47442424-94D21C71-B0F9-47CA-9AC8-CF69C03A9F0DQ47669193-0F9F98FD-DEA6-4EF9-A6FB-9FBC19385CE4Q47807022-8C8039CA-F1B2-4D9D-BA59-9C4D982A6B21Q47864597-BD22B3E6-4481-4703-B2E1-C2674BAD4260Q47916882-EAF0E5F0-471F-4F8B-B755-44665DDB0191Q48873225-E9128B09-E0DC-442F-BA73-46285C808EFEQ51242172-1DD22E4F-C18D-4DF6-8F97-053BD90B5212Q51490154-F2CCCFD7-6FB3-49D2-932B-ACC23DA5080EQ51516174-E304181C-46C8-4A5F-A08C-4ABB346150BBQ53394160-C5C3A558-B831-4FF1-BBA0-FC3AE1C51C92Q57341424-8BB7119A-CACB-40FA-83DD-1B80278F468CQ57341457-C189D52D-A5AD-42F1-A0D9-47A60EC1467EQ57341679-9E31BC63-6852-40EC-A4AF-F96E30B4F43DQ57346976-DD10D23A-9E62-4196-81A3-980ABE5E545FQ57347444-D8CF6BD7-53EA-4C05-A387-CD41300362E5
P2860
description
im Juni 2013 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в червні 2013
@uk
name
Biomimetic Hydrogel-Based Actuating Systems
@en
Biomimetic Hydrogel-Based Actuating Systems
@nl
type
label
Biomimetic Hydrogel-Based Actuating Systems
@en
Biomimetic Hydrogel-Based Actuating Systems
@nl
prefLabel
Biomimetic Hydrogel-Based Actuating Systems
@en
Biomimetic Hydrogel-Based Actuating Systems
@nl
P2860
P356
P1476
Biomimetic Hydrogel-Based Actuating Systems
@en
P2860
P304
P356
10.1002/ADFM.201203692
P407
P50
P577
2013-06-05T00:00:00Z