The full text of this article hosted at iucr.org is unavailable due to technical difficulties.

Journal of Morphology

Volume 202, Issue 1
Article

Structure and development of iridescent butterfly scales: Lattices and laminae

H. Ghiradella

Department of Biological Sciences, State University of New York at Albany, Albany, New York 12222

Search for more papers by this author
First published: October 1989
https://doi.org/10.1002/jmor.1052020106
Cited by: 90

Abstract

Iridescent butterfly scales are structurally colored, relying upon the interaction of light with detailed architecture to produce their color. In some iridescent scales, the reflective elements are contained within the body of the scale and come in two basic forms, lattices that produce diffraction colors (analogous to those produced by opal), and stacks of laminae that produce thin‐film interference colors (analogous to those produced by soap or oil films). Both structures are remarkably complex and precise, yet each is only part of the total edifice built by the cell that makes the scale.

To understand better how a cell can produce lattices or thin‐film laminae, I studied the development of iridescent scales from two lycaenid butterflies. The presence of diffraction and thin‐film scales in the same family (and in some cases on the same individual) suggests that the two types must be developmentally related; yet these results yield no clear explanation as to how. The diffraction lattice appears to be shaped within the boundaries of the scale cell by means of a convoluted series of membranes in which the smooth endoplasmic reticulum plays an important part. The thin‐film interference laminae appear to result from the condensation of a network of filaments and tubes secreted outside the boundaries of the cell. This paper outlines the developmental histories of both types of scale and discusses the developmental implications of the mechanisms by which they form.

Number of times cited: 90

  • Bodo D. Wilts, Xiaoyuan Sheng, Mirko Holler, Ana Diaz, Manuel Guizar‐Sicairos, Jörg Raabe, Robert Hoppe, Shu‐Hao Liu, Richard Langford, Olimpia D. Onelli, Duyu Chen, Salvatore Torquato, Ullrich Steiner, Christian G. Schroer, Silvia Vignolini and Alessandro Sepe, Evolutionary‐Optimized Photonic Network Structure in White Beetle Wing Scales, Advanced Materials, 30, 19, (2017).
    Wiley Online Library
  • Sébastien R. Mouchet and Pete Vukusic, Structural Colours in Lepidopteran Scales, , 10.1016/bs.aiip.2017.11.002, (2018).
    Crossref
  • Robert W. Corkery and Eric C. Tyrode, On the colour of wing scales in butterflies: iridescence and preferred orientation of single gyroid photonic crystals, Interface Focus, 7, 4, (20160154), (2017).
    Crossref
  • Bodo D. Wilts, Benjamin Apeleo Zubiri, Michael A. Klatt, Benjamin Butz, Michael G. Fischer, Stephen T. Kelly, Erdmann Spiecker, Ullrich Steiner and Gerd E. Schröder-Turk, Butterfly gyroid nanostructures as a time-frozen glimpse of intracellular membrane development, Science Advances, 10.1126/sciadv.1603119, 3, 4, (e1603119), (2017).
    Crossref
  • Makoto Kazama, Mai Ichinei, Saori Endo, Masaki Iwata, Akiya Hino and Joji M. Otaki, Species‐dependent microarchitectural traits of iridescent scales in the triad taxa of Ornithoptera birdwing butterflies, Entomological Science, 20, 1, (255-269), (2017).
    Wiley Online Library
  • Natalia Dushkina, Sema Erten and Akhlesh Lakhtakia, Coloration and Structure of the Wings of Chorinea sylphina Bates , Journal of the Lepidopterists’ Society, 10.18473/lepi.v71i1.a2, 71, 1, (1-11), (2017).
    Crossref
  • M. Thomé, L. Nicole and S. Berthier, Sol-gel molding: a new observation method of multiscaled structures, Materials Today: Proceedings, 10.1016/j.matpr.2017.04.108, 4, 4, (5013-5022), (2017).
    Crossref
  • Stanislav N. Gorb and Elena V. Gorb, Insect-Inspired Architecture: Insects and Other Arthropods as a Source for Creative Design in Architecture, Biomimetic Research for Architecture and Building Construction, 10.1007/978-3-319-46374-2_4, (57-83), (2016).
    Crossref
  • Liping Wu, Jiaqing He, Wen Shang, Tao Deng, Jiajun Gu, Huilan Su, Qinglei Liu, Wang Zhang and Di Zhang, Optical Functional Materials Inspired by Biology, Advanced Optical Materials, 4, 2, (195-224), (2015).
    Wiley Online Library
  • Ranajay Ghosh, Hamid Ebrahimi and Ashkan Vaziri, Frictional effects in biomimetic scales engagement, EPL (Europhysics Letters), 10.1209/0295-5075/113/34003, 113, 3, (34003), (2016).
    Crossref
  • Bodo D. Wilts, Marco A. Giraldo and Doekele G. Stavenga, Unique wing scale photonics of male Rajah Brooke’s birdwing butterflies, Frontiers in Zoology, 13, 1, (2016).
    Crossref
  • Andrew R. Parker, Biomimetics of Optical Nanostructures, Encyclopedia of Nanotechnology, 10.1007/978-94-017-9780-1_393, (359-371), (2016).
    Crossref
  • Michio Imafuku and Naomichi Ogihara, Wing Scale Orientation Alters Reflection Directions in the Green Hairstreak Chrysozephyrus smaragdinus (Lycaenidae; Lepidoptera) , Zoological Science, 10.2108/zs160041, 33, 6, (616-622), (2016).
    Crossref
  • Sigrid Zobl, Willi Salvenmoser, Thorsten Schwerte, Ille C Gebeshuber and Manfred Schreiner, Morpho peleidesbutterfly wing imprints as structural colour stamp, Bioinspiration & Biomimetics, 11, 1, (016006), (2016).
    Crossref
  • Quentin Willot, Priscilla Simonis, Jean-Pol Vigneron, Serge Aron and Matthew Shawkey, Total Internal Reflection Accounts for the Bright Color of the Saharan Silver Ant, PLOS ONE, 11, 4, (e0152325), (2016).
    Crossref
  • Sébastien R. Mouchet, Eloise Van Hooijdonk, Victoria L. Welch, Pierre Louette, Jean-François Colomer, Bao-Lian Su and Olivier Deparis, Liquid-induced colour change in a beetle: the concept of a photonic cell, Scientific Reports, 6, 1, (2016).
    Crossref
  • Liping Wu, Wang Zhang and Di Zhang, Engineering Gyroid‐Structured Functional Materials via Templates Discovered in Nature and in the Lab, Small, 11, 38, (5004-5022), (2015).
    Wiley Online Library
  • Andrew Richard Parker and Helen Elizabeth Townley, Making photonic structures via cell culture:Morphobutterfly scales, Bioinspired, Biomimetic and Nanobiomaterials, 4, 1, (68), (2015).
    Crossref
  • Vinodkumar Saranathan, Ainsley E. Seago, Alec Sandy, Suresh Narayanan, Simon G. J. Mochrie, Eric R. Dufresne, Hui Cao, Chinedum O. Osuji and Richard O. Prum, Structural Diversity of Arthropod Biophotonic Nanostructures Spans Amphiphilic Phase-Space, Nano Letters, 15, 6, (3735), (2015).
    Crossref
  • Benjamin Winter, Benjamin Butz, Christel Dieker, Gerd E. Schröder-Turk, Klaus Mecke and Erdmann Spiecker, Coexistence of both gyroid chiralities in individual butterfly wing scales ofCallophrys rubi, Proceedings of the National Academy of Sciences, 112, 42, (12911), (2015).
    Crossref
  • Antónia Monteiro, Xiaoling Tong, Ashley Bear, Seng Fatt Liew, Shivam Bhardwaj, Bethany R. Wasik, April Dinwiddie, Carole Bastianelli, Wei Fun Cheong, Markus R. Wenk, Hui Cao, Kathleen L. Prudic and Artyom Kopp, Differential Expression of Ecdysone Receptor Leads to Variation in Phenotypic Plasticity across Serial Homologs, PLOS Genetics, 11, 9, (e1005529), (2015).
    Crossref
  • Di Zhang, Wang Zhang, Jiajun Gu, Tongxiang Fan, Qinglei Liu, Huilan Su and Shenmin Zhu, Inspiration from butterfly and moth wing scales: Characterization, modeling, and fabrication, Progress in Materials Science, 10.1016/j.pmatsci.2014.10.003, 68, (67-96), (2015).
    Crossref
  • Jong Seto, Ashit Rao and Helmut Cölfen, Hierarchically Nanostructured Biological Materials, Advanced Hierarchical Nanostructured Materials, (35-70), (2014).
    Wiley Online Library
  • Bodo D. Wilts, Heather M. Whitney, Beverley J. Glover, Ullrich Steiner and Silvia Vignolini, Natural Helicoidal Structures: Morphology, Self-assembly and Optical Properties, Materials Today: Proceedings, 1, (177), (2014).
    Crossref
  • S. Yoshioka, H. Fujita, S. Kinoshita and B. Matsuhana, Alignment of crystal orientations of the multi-domain photonic crystals in Parides sesostris wing scales, Journal of The Royal Society Interface, 10.1098/rsif.2013.1029, 11, 92, (20131029-20131029), (2013).
    Crossref
  • M. E. McNamara, V. Saranathan, E. R. Locatelli, H. Noh, D. E. G. Briggs, P. J. Orr and H. Cao, Cryptic iridescence in a fossil weevil generated by single diamond photonic crystals, Journal of The Royal Society Interface, 10.1098/rsif.2014.0736, 11, 100, (20140736-20140736), (2014).
    Crossref
  • Bodo D Wilts, Natasja IJbema and Doekele G Stavenga, Pigmentary and photonic coloration mechanisms reveal taxonomic relationships of the Cattlehearts (Lepidoptera: Papilionidae: Parides), BMC Evolutionary Biology, 14, 1, (2014).
    Crossref
  • Bodo D. Wilts, Primož Pirih, Kentaro Arikawa and Doekele G. Stavenga, Shiny wing scales cause spec(tac)ular camouflage of the angled sunbeam butterfly, uretis acuta, Biological Journal of the Linnean Society, 109, 2, (279-289), (2013).
    Wiley Online Library
  • Wallace F. Marshall, Differential Geometry Meets the Cell, Cell, 154, 2, (265), (2013).
    Crossref
  • Shuichi Kinoshita, Introduction to Nonequilibrium Phenomena, Pattern Formations and Oscillatory Phenomena, 10.1016/B978-0-12-397014-5.00001-8, (1-59), (2013).
    Crossref
  • Natalia Dushkina and Akhlesh Lakhtakia, Structural Colors, Engineered Biomimicry, 10.1016/B978-0-12-415995-2.00011-8, (267-303), (2013).
    Crossref
  • Stephen T Hyde, D’Arcy Thompson’s Legacy in Contemporary Studies of Patterns and Morphology, Interdisciplinary Science Reviews, 38, 1, (12), (2013).
    Crossref
  • Shuichi Kinoshita, Bibliography, Bionanophotonics, 10.1201/b15260-10, (473-489), (2013).
    Crossref
  • Michio IMAFUKU, Hiroshi Y. KUBOTA and Kei INOUYE, Wing colors based on arrangement of the multilayer structure of wing scales in lycaenid butterflies (Insecta: Lepidoptera), Entomological Science, 15, 4, (400-407), (2012).
    Wiley Online Library
  • B. D. Wilts, K. Michielsen, J. Kuipers, H. De Raedt and D. G. Stavenga, Brilliant camouflage: photonic crystals in the diamond weevil, Entimus imperialis, Proceedings of the Royal Society B: Biological Sciences, 279, 1738, (2524), (2012).
    Crossref
  • Kyungjae Chung, Sunkyu Yu, Chul‐Joon Heo, Jae Won Shim, Seung‐Man Yang, Moon Gyu Han, Hong‐Seok Lee, Yongwan Jin, Sang Yoon Lee, Namkyoo Park and Jung H. Shin, Flexible, Angle‐Independent, Structural Color Reflectors Inspired by Morpho Butterfly Wings, Advanced Materials, 24, 18, (2375-2379), (2012).
    Wiley Online Library
  • Yuya Fukano, Toshiyuki Satoh, Tadao Hirota, Yudai Nishide and Yoshiaki Obara, Geographic expansion of the cabbage butterfly (Pieris rapae) and the evolution of highly UV‐reflecting females, Insect Science, 19, 2, (239-246), (2011).
    Wiley Online Library
  • Stuart A. Boden, Asa Asadollahbaik, Harvey N. Rutt and Darren M. Bagnall, Helium ion microscopy of Lepidoptera scales, Scanning, 34, 2, (107-120), (2011).
    Wiley Online Library
  • Srećko B. Ćurčić, Dejan V. Pantelić, Božidar P.M. Ćurčić, Svetlana N. Savić‐Šević, Slobodan E. Makarov, Vesna B. Lačković, Milica M. Labudović‐Borović, Nina B. Ćurčić and Dejan V. Stojanović, Micro‐ and nanostructures of iridescent wing scales in purple emperor butterflies (Lepidoptera: Apatura ilia and A. iris), Microscopy Research and Technique, 75, 7, (968-976), (2012).
    Wiley Online Library
  • Ainsley Seago and Vinodkumar Saranathan, Photonic Crystals in Beetles, Nature's Nanostructures, 10.1201/b11618-15, (313-326), (2012).
    Crossref
  • Andrew Parker, Torben Lenau and Akira Saito, Biomimetics of Optical Nanostructures, Biomimetics in Photonics, 10.1201/b13067-4, (55-116), (2013).
    Crossref
  • LiPing Jiang, BiQin Dong, XiaoHan Liu, Feng Liu and Jian Zi, Structural origin of sexual dichromatic coloration and luster in the beetle Goliathus cacicus, Chinese Science Bulletin, 57, 24, (3211), (2012).
    Crossref
  • S. Chattopadhyay, Y.F. Huang, K-H. Chen and L-C. Chen, Biomimetic nanostructures for anti-reflection (AR) devices, Optical Biomimetics, 10.1533/9780857097651.108, (108-146), (2012).
    Crossref
  • A.R. Parker, Natural photonic structures: an overview, Optical Biomimetics, 10.1533/9780857097651.1, (1-20e), (2012).
    Crossref
  • S. Wickham, L. Poladian, M.C.J. Large and P. Vukusic, Control of iridescence in natural photonic structures: the case of butterfly scales, Optical Biomimetics, 10.1533/9780857097651.147, (147-176e), (2012).
    Crossref
  • Marcus R. Kronforst, Gregory S. Barsh, Artyom Kopp, James Mallet, Antónia Monteiro, Sean P. Mullen, Meredith Protas, Erica B. Rosenblum, Christopher J. Schneider and Hopi E. Hoekstra, Unraveling the thread of nature’s tapestry: the genetics of diversity and convergence in animal pigmentation, Pigment Cell & Melanoma Research, 25, 4, (411-433), (2012).
    Wiley Online Library
  • L.P. Biró and J.P. Vigneron, Photonic nanoarchitectures in butterflies and beetles: valuable sources for bioinspiration, Laser & Photonics Reviews, 5, 1, (27-51), (2010).
    Wiley Online Library
  • Darrell J. Kemp and Ronald L. Rutowski, The Role of Coloration in Mate Choice and Sexual Interactions in Butterflies, , 10.1016/B978-0-12-380896-7.00002-2, (55-92), (2011).
    Crossref
  • Bodo D. Wilts, Primož Pirih and Doekele G. Stavenga, Spectral reflectance properties of iridescent pierid butterfly wings, Journal of Comparative Physiology A, 197, 6, (693), (2011).
    Crossref
  • Primož Pirih, Bodo D. Wilts and Doekele G. Stavenga, Spatial reflection patterns of iridescent wings of male pierid butterflies: curved scales reflect at a wider angle than flat scales, Journal of Comparative Physiology A, 197, 10, (987), (2011).
    Crossref
  • Young Min Song, Gyeong Cheol Park, Sung Jun Jang, Jong Hoon Ha, Jae Su Yu and Yong Tak Lee, Multifunctional light escaping architecture inspired by compound eye surface structures: From understanding to experimental demonstration, Optics Express, 19, S2, (A157), (2011).
    Crossref
  • Gábor Piszter, Krisztián Kertész, Zofia Vértesy, Zsolt Bálint and László Péter Biró, Color based discrimination of chitin–air nanocomposites in butterfly scales and their role in conspecific recognition, Anal. Methods, 3, 1, (78), (2011).
    Crossref
  • Heeso Noh, Seng Fatt Liew, Vinodkumar Saranathan, Simon G. J. Mochrie, Richard O. Prum, Eric R. Dufresne and Hui Cao, How Noniridescent Colors Are Generated by Quasi‐ordered Structures of Bird Feathers, Advanced Materials, 22, 26‐27, (2871-2880), (2010).
    Wiley Online Library
  • V. Saranathan, C. O. Osuji, S. G. J. Mochrie, H. Noh, S. Narayanan, A. Sandy, E. R. Dufresne and R. O. Prum, Structure, function, and self-assembly of single network gyroid (I4132) photonic crystals in butterfly wing scales, Proceedings of the National Academy of Sciences, 107, 26, (11676), (2010).
    Crossref
  • Helen Ghiradella, Insect Cuticular Surface Modifications, Advances in Insect Physiology: Insect Integument and Colour, 10.1016/S0065-2806(10)38006-4, (135-180), (2010).
    Crossref
  • Heeso Noh, Seng Fatt Liew, Vinodkumar Saranathan, Richard O. Prum, Simon G. J. Mochrie, Eric R. Dufresne and Hui Cao, Contribution of double scattering to structural coloration in quasiordered nanostructures of bird feathers, Physical Review E, 10.1103/PhysRevE.81.051923, 81, 5, (2010).
    Crossref
  • L. Poladian, S. Wickham, K. Lee and M. C.J Large, Iridescence from photonic crystals and its suppression in butterfly scales, Journal of The Royal Society Interface, 6, Suppl_2, (S233), (2009).
    Crossref
  • Jessica D. Schiffman and Caroline L. Schauer, Solid state characterization of α-chitin from Vanessa cardui Linnaeus wings, Materials Science and Engineering: C, 29, 4, (1370), (2009).
    Crossref
  • P. Vukusic, Evolutionary Photonics with a Twist, Science, 325, 5939, (398), (2009).
    Crossref
  • Zakaria A. Almsherqi, Tomas Landh, Sepp D. Kohlwein and Yuru Deng, Chapter 6 Cubic Membranes, , 10.1016/S1937-6448(08)02006-6, (275-342), (2009).
    Crossref
  • A. R Parker, Natural photonics for industrial inspiration, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 367, 1894, (1759), (2009).
    Crossref
  • Pablo Perez Goodwyn, Yasunori Maezono, Naoe Hosoda and Kenji Fujisaki, Waterproof and translucent wings at the same time: problems and solutions in butterflies, Naturwissenschaften, 96, 7, (781), (2009).
    Crossref
  • R. O Prum, E. R Dufresne, T. Quinn and K. Waters, Development of colour-producing  -keratin nanostructures in avian feather barbs, Journal of The Royal Society Interface, 6, Suppl_2, (S253), (2009).
    Crossref
  • B. D Wilts, H. L Leertouwer and D. G Stavenga, Imaging scatterometry and microspectrophotometry of lycaenid butterfly wing scales with perforated multilayers, Journal of The Royal Society Interface, 6, Suppl_2, (S185), (2009).
    Crossref
  • Eric R. Dufresne, Heeso Noh, Vinodkumar Saranathan, Simon G. J. Mochrie, Hui Cao and Richard O. Prum, Self-assembly of amorphous biophotonic nanostructures by phase separation, Soft Matter, 5, 9, (1792), (2009).
    Crossref
  • Stephen T. Hyde, Michael O'Keeffe and Davide M. Proserpio, A Short History of an Elusive Yet Ubiquitous Structure in Chemistry, Materials, and Mathematics, Angewandte Chemie International Edition, 47, 42, (7996-8000), (2008).
    Wiley Online Library
  • Stephen T. Hyde, Michael O'Keeffe and Davide M. Proserpio, Netze und Gyroide: wenig bekannt und doch in Chemie, Materialwissenschaften und Mathematik allgegenwärtig, Angewandte Chemie, 120, 42, (8116-8121), (2008).
    Wiley Online Library
  • Shinya YOSHIOKA, Structural color of the lepidopteran scale: optical effects of microstructure, curvature and overlap of the scales, Hikaku seiri seikagaku(Comparative Physiology and Biochemistry), 10.3330/hikakuseiriseika.25.86, 25, 3, (86-95), (2008).
    Crossref
  • A.L Ingram and A.R Parker, A review of the diversity and evolution of photonic structures in butterflies, incorporating the work of John Huxley (The Natural History Museum, London from 1961 to 1990), Philosophical Transactions of the Royal Society B: Biological Sciences, 10.1098/rstb.2007.2258, 363, 1502, (2465-2480), (2008).
    Crossref
  • S Kinoshita, S Yoshioka and J Miyazaki, Physics of structural colors, Reports on Progress in Physics, 10.1088/0034-4885/71/7/076401, 71, 7, (076401), (2008).
    Crossref
  • Zsolt Bálint, Pierre Boyer, Krisztián Kertész and László P. Biró, Observations on the spectral reflectances of certain high AndeanPenaincisaliaandThecloxurina, with the description of a new species (Lepidoptera: Lycaenidae: Eumaeini), Journal of Natural History, 42, 25-26, (1793), (2008).
    Crossref
  • K Michielsen and D.G Stavenga, Gyroid cuticular structures in butterfly wing scales: biological photonic crystals, Journal of The Royal Society Interface, 10.1098/rsif.2007.1065, 5, 18, (85-94), (2008).
    Crossref
  • Yoshiaki Obara, Gaku Ozawa, Yuya Fukano, Kenta Watanabe and Toshiyuki Satoh, Mate Preference in Males of the Cabbage Butterfly, Pieris rapae crucivora, Changes Seasonally with the Change in Female UV Color, Zoological Science, 25, 1, (1), (2008).
    Crossref
  • RONALD L. RUTOWSKI, JOSEPH M. MACEDONIA, JUSTIN W. MERRY, NATHAN I. MOREHOUSE, KASEY YTURRALDE, LAURA TAYLOR‐TAFT, DIANN GAALEMA, DARRELL J. KEMP and RANDI S. PAPKE, Iridescent ultraviolet signal in the orange sulphur butterfly (Colias eurytheme): spatial, temporal and spectral properties, Biological Journal of the Linnean Society, 90, 2, (349-364), (2007).
    Wiley Online Library
  • L´szló Péter Biró, Zsolt Bálint, Krisztián Kertész, Zofia Vértesy, Géza István Márk, Levente Tapasztó, Jean-Pol Vigneron, Virginie Lousse and Laszlo Peter Biro, Photonic Crystal Structures of Biologic Origin: Butterfly Wing Scales, MRS Proceedings, 10.1557/PROC-1014-AA07-08, 1014, (2011).
    Crossref
  • Andrew R. Parker and Helen E. Townley, Biomimetics of photonic nanostructures, Nature Nanotechnology, 10.1038/nnano.2007.152, 2, 6, (347-353), (2007).
    Crossref
  • S. Wickham, M. C.J Large, L. Poladian and L. S Jermiin, Exaggeration and suppression of iridescence: the evolution of two-dimensional butterfly structural colours, Journal of The Royal Society Interface, 3, 6, (99), (2006).
    Crossref
  • Shuichi Kinoshita and Shinya Yoshioka, Structural Colors in Nature: The Role of Regularity and Irregularity in the Structure, ChemPhysChem, 6, 8, (1442-1459), (2005).
    Wiley Online Library
  • Stanislav Gorb, Functional Surfaces in Biology, Biomimetics, 10.1201/9781420037715.ch15, (381-397), (2009).
    Crossref
  • A. R. Parker, A geological history of reflecting optics, Journal of The Royal Society Interface, 2, 2, (1), (2005).
    Crossref
  • R.L Rutowski, J.M Macedonia, N Morehouse and L Taylor-Taft, Pterin pigments amplify iridescent ultraviolet signal in males of the orange sulphur butterfly, Colias eurytheme, Proceedings of the Royal Society B: Biological Sciences, 272, 1578, (2329), (2005).
    Crossref
  • Morley O. Stone and Rajesh R. Naik, Biomimetic Electromagnetic Devices, Encyclopedia of Smart Materials, (2002).
    Wiley Online Library
  • Victor R. Townsend and Bruce E. Felgenhauer, Ultrastructure of the cuticular scales of lynx spiders (Araneae, Oxyopidae) and jumping spiders (Araneae, Salticidae), Journal of Morphology, 240, 1, (77-92), (1999).
    Wiley Online Library
  • H. Frederik Nijhout, Hormonal Control in Larval Development and Evolution—Insects, The Origin and Evolution of Larval Forms, 10.1016/B978-012730935-4/50008-0, (217-254), (1999).
    Crossref
  • Peter J. Herring, Reflective systems in aquatic animals, Comparative Biochemistry and Physiology Part A: Physiology, 109, 3, (513), (1994).
    Crossref
  • Helen Ghiradella, Structure of butterfly scales: Patterning in an insect cuticle, Microscopy Research and Technique, 27, 5, (429-438), (2005).
    Wiley Online Library
  • Helen Ghiradella, Light and color on the wing: structural colors in butterflies and moths, Applied Optics, 30, 24, (3492), (1991).
    Crossref
  • Liping Wu, Wanlin Wang, Wang Zhang, Huilan Su, Jiajun Gu, Qinglei Liu, Di Zhang, Dejan Pantelić and Branislav Jelenković, Optical Performance Study of Gyroid‐Structured TiO2 Photonic Crystals Replicated from Natural Templates Using a Sol‐Gel Method, Advanced Optical Materials, 1800064, (2018).
    Wiley Online Library
  • Liping Wu, Wanlin Wang, Wang Zhang, Huilan Su, Qinglei Liu, Jiajun Gu, Tao Deng and Di Zhang, Highly sensitive, reproducible and uniform SERS substrates with a high density of three-dimensionally distributed hotspots: gyroid-structured Au periodic metallic materials, NPG Asia Materials, 10.1038/am.2017.230, 10, 1, (e462), (2018).
    Crossref
  • Bodo D. Wilts and Vinodkumar Saranathan, A Literal Elytral Rainbow: Tunable Structural Colors Using Single Diamond Biophotonic Crystals in Pachyrrhynchus congestus Weevils, Small, 1802328, (2018).
    Wiley Online Library