Bio-inspired band-gap tunable elastic optical multilayer fibers.
about
25th anniversary article: ordered polymer structures for the engineering of photons and phonons.Light-Directed Writing of Chemically Tunable Narrow-Band Holographic SensorsA highly conspicuous mineralized composite photonic architecture in the translucent shell of the blue-rayed limpet.Structural colour from helicoidal cell-wall architecture in fruits of Margaritaria nobilis.Mechanochromic photonic-crystal fibers based on continuous sheets of aligned carbon nanotubes.Biomimicry of multifunctional nanostructures in the neck feathers of mallard (Anas platyrhynchos L.) drakes."Green" electronics: biodegradable and biocompatible materials and devices for sustainable future.Bioinspired engineering of thermal materials.The physics of pollinator attraction.Interactions between colour-producing mechanisms and their effects on the integumentary colour palette.Generating Bulk-Scale Ordered Optical Materials Using Shear-Assembly in Viscoelastic Media.Analysing photonic structures in plants.Flexible Distributed Bragg Reflectors from Nanocolumnar TemplatesMechanochromic photonic gels.Spectral Transition in Bio-Inspired Self-Assembled Peptide Nucleic Acid Photonic Crystals.Progress and Opportunities in Soft Photonics and Biologically Inspired Optics.Cellulose-Based Biomimetics and Their Applications.Surface Molding of Microscale Hydrogels with Microactuation Functionality.Glucose-Sensitive Hydrogel Optical Fibers Functionalized with Phenylboronic Acid.Multiscale instabilities in soft heterogeneous dielectric elastomers.Harnessing viscoelasticity and instabilities for tuning wavy patterns in soft layered composites.Mechanochromic Fibers with Structural Color.Tarantula-Inspired Noniridescent Photonics with Long-Range OrderCharacterization of a Mechanically Tunable Gyroid Photonic Crystal Inspired by the Butterfly Parides SesostrisPolymeric biomaterials for biophotonic applicationsNanostructural Colouration in Malaysian Plants: Lessons for Biomimetics and Biomaterials
P2860
Q27011228-DFC61FA4-781C-4284-A569-BC139265BD42Q30054293-B4391120-B68E-4A81-AFD8-DFE95C890A2AQ30625296-EFE14260-0E37-446E-B6E0-D905A2A4FE1FQ30830563-8304CD78-6764-43FF-8EE3-37558821BAC6Q30902100-066AE3DD-8150-4EC9-8BCA-FD22D9D585CDQ37714759-F0144B16-E783-470A-A1D2-B54DDC3C83EEQ38152208-6DF1AC3E-9444-448A-B7AA-5FB42AB8C9F6Q38255697-7A28CF3F-90A4-49D0-A3E2-1DF5EC0E2586Q39028658-E1BB7D46-8BEF-4A46-9BC9-48D53971B166Q39323472-A3748EFC-BE51-4BD7-B3D1-CB6CD3E32AFCQ41343910-5048B326-C094-4DA4-956A-63FC1DA81C4CQ41845196-1CB9451A-6242-46D9-A5E9-52721FC5475AQ41941497-450958FD-896A-4A1B-9C51-702A04739594Q46098886-2699A858-40C9-4454-8A68-B0CDD8F3F966Q46609347-EC84E277-7242-4D93-A6DB-21263DB6C7A6Q47422779-245E2689-1E68-4A89-BF41-004C59EA8165Q47716694-974041AD-3FF3-4BF8-A418-BF31E8D2F330Q48127756-9DFCDADB-3644-410E-9838-ABEF75E93A5BQ50894412-A805E7E6-AB10-4AAC-BDC9-BE8FCB0DB2DBQ51114058-D9D8BF27-A191-47AD-BC9D-FCB11FBD0341Q51387456-6C8B105D-D526-4F07-8F78-AA8243399ABDQ51702350-F0E694D9-86E6-432A-BFF1-3ABB778BEC69Q54203937-D95D539F-7973-4EE8-95BA-BA4F61413567Q57915547-6939E39E-BB40-4781-B892-D06B9133EB4BQ58799178-4FA0C907-640D-465F-8D73-5F7447EC8FC3Q59059426-C4F4967A-ECB0-492B-8672-F66887CA0F2A
P2860
Bio-inspired band-gap tunable elastic optical multilayer fibers.
description
2013 nî lūn-bûn
@nan
2013年の論文
@ja
2013年論文
@yue
2013年論文
@zh-hant
2013年論文
@zh-hk
2013年論文
@zh-mo
2013年論文
@zh-tw
2013年论文
@wuu
2013年论文
@zh
2013年论文
@zh-cn
name
Bio-inspired band-gap tunable elastic optical multilayer fibers.
@en
type
label
Bio-inspired band-gap tunable elastic optical multilayer fibers.
@en
prefLabel
Bio-inspired band-gap tunable elastic optical multilayer fibers.
@en
P2093
P2860
P356
P1433
P1476
Bio-inspired band-gap tunable elastic optical multilayer fibers.
@en
P2093
Alfred Lethbridge
Jeremy J Baumberg
Joanna Aizenberg
Mathias Kolle
Peter Vukusic
P2860
P304
P356
10.1002/ADMA.201203529
P407
P577
2013-01-27T00:00:00Z