Photonic effects in natural nanostructures on Morpho cypris and Greta oto butterfly wings

Barrera-Patiño, Claudia P.; Vollet‐Filho, José Dirceu; Teixeira-Rosa, R. G.; Quiroz, Heiddy P.; Dussán, A.; Inada, Natália Mayumi; Bagnato, Vanderlei Salvador; Rey‐González, R. R.

doi:10.1038/s41598-020-62770-w

Cited by 29 publications

(21 citation statements)

References 30 publications

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“…[ 40–44 ] Such grating architectures composed of cross‐hatch interior lamellae mutually with perpendicular intersections are also reported for ring‐banded PEA crystallized at T c = 28–30 °C known for displaying bio‐mimetic structures for iridescent properties, [ 39 ] which also resemble some of nature's crystal assemblies for bio‐photonic structures to produce complex light diffractions. [ 44–49 ] Such interior periodic assembly array in PBA ring‐banded spherulites is quite similar to those in beetles’ exoskeleton scales with a photonic crystal structure reported by Bartl, et. al.…”

Section: Resultsmentioning

confidence: 88%

Microstructural Periodic Arrays in Poly(Butylene Adipate) Featured with Photonic Crystal Aggregates

Nagarajan

Yang

2021

Macromol. Rapid Commun.

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Poly(butylene adipate) (PBA) self‐aggregation into unique periodicity correlating to its interfacial photonic properties is probed in detail. Investigations on the unique periodic morphology and top‐surface and interior architectures in specifically crystallized PBA are focused on its novel photonic patterns with periodic gratings. Detailed analysis of the interior lamellae from ringless to periodically ordered aggregates (crystallized at 33–35 °C vs. Tc = 30 °C) serves as ideal comparisons. Each interior arc‐shape shell is composed of tangential and radial lamellae mutually intersecting at 90o angle. The interior layer thickness in SEM‐revealed arc‐shape shish‐kebab shell is exactly equal to the optical inter‐band spacing (≈6 µm). A 3D assembly mechanism of periodically banded PBA crystals is proposed, where the orderly arrays on top surfaces as well as the interior microstructures of strut‐rib alternate‐layered assembly resemble nature's photonic crystals and collectively account for the interfacial photonic properties in the ring‐banded PBA crystal that is novel and has potential applications in future.

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Section: Resultsmentioning

confidence: 88%

Microstructural Periodic Arrays in Poly(Butylene Adipate) Featured with Photonic Crystal Aggregates

Nagarajan

Yang

2021

Macromol. Rapid Commun.

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“…Common natural examples of static photonic structures include the alternating layers found in butterfly wings, [2,3] the opal-like structures of bird feathers, [4,5] and beetle carapaces [6,7] (Figure 1a-c). However, biology presents not only static but also dynamic color.…”

Section: Scope Of the Articlementioning

confidence: 99%

“…This periodic modulation creates a “Bragg reflector” that selectively reflects light of wavelengths that fall in the forbidden bandgap of the structure, following Bragg's law (Equation ):

λ = 2 d n_{avg} \cos θ

where λ denotes the bandgap's central wavelength, n avg the average refractive index, d the thickness of one periodic structure, and θ the angle of incident light. Common natural examples of static photonic structures include the alternating layers found in butterfly wings, [ 2,3 ] the opal‐like structures of bird feathers, [ 4,5 ] and beetle carapaces [ 6,7 ] ( Figure a–c). However, biology presents not only static but also dynamic color.…”

Section: General Introductionmentioning

confidence: 99%

Temperature‐Responsive Photonic Devices Based on Cholesteric Liquid Crystals

Zhang

Froyen

Schenning

et al. 2021

Advanced Photonics Research

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Cholesteric liquid crystals (CLCs) are a major class of photonic materials that display selective reflection properties arising from their helical ordering. The temperature response of CLCs, comprising dynamic reflection color changes upon variation of temperature, is exploited using material systems consisting of small mesogenic molecules, polymer‐dispersed liquid crystals (PDLCs), polymer‐stabilized liquid crystals (PSLCs), or liquid‐crystalline polymers. Taking advantage of the easy processability and flexibility of the molecular design, these temperature‐responsive CLCs are fabricated into different forms of photonic devices, including cells, coatings, free‐standing films, and 3D objects. Temperature‐responsive devices developed from CLCs are integrated for application in temperature sensors, energy‐saving smart windows, smart labels, actuators, and adding aesthetically pleasing features to common objects. Herein, the device capabilities of the different material systems of temperature‐responsive CLCs are summarized: small mesogenic molecules, PDLCs, PSLCs, and CLC polymers. For each system, examples of different device forms are presented, with their temperature responsiveness and the underlying mechanisms discussed. In addition, the potential of each material system for future device applications and product developments is envisioned.

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“…Insects are notable for the diversity of nanostructures with optical activity found on their cuticles, which have been reported to give rise to diffraction, interference, reflectance, and iridescence effects [5] . Such biological nanostructures often lead to striking visual phenomena: for example, the structural coloration [6] and iridescence of the wings of Morpho butterflies [7,8] is attributed to multiple slit interference effects from light interactions with periodic grating-like structures.…”

Section: Introductionmentioning

confidence: 99%

Nanostructure-derived anti-reflectivity in leafhopper brochosomes

Banerjee

Burks

Bialik

et al. 2022

Preprint

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Understanding how insect-derived biomaterials interact with light has led to new advances and interdisciplinary insights in entomology and physics. Leafhoppers are insects that coat themselves with highly ordered biological nanostructures known as brochosomes. Brochosomes are thought to provide a range of protective properties to leafhoppers, such as hydrophobicity and anti-reflectivity, which has inspired the development of synthetic brochosomes that mimic their structures. Despite recent progress, the ultra-high anti-reflective properties of brochosome structures are not fully understood. In this work, we use a combination of experiments and computational modeling to understand the structure-, material-, and polarization-dependent optical properties of brochosomes modeled on the geometries found in three leafhopper species. Our results show that that Fano resonance is responsible for the ultra-high anti-reflectivity of brochosomes. Whereas prior work has focused on computational modeling of idealized pitted particles, our work shows that light-matter interactions with brochosome structures can be tuned by varying the geometry of their cage-like nanoscale features and by changing the arrangement of multi-particle assemblies. Broadly, this work establishes principles for the guided design of new optically active materials inspired by these unique insect nanostructures.

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Photonic effects in natural nanostructures on Morpho cypris and Greta oto butterfly wings

Cited by 29 publications

References 30 publications

Microstructural Periodic Arrays in Poly(Butylene Adipate) Featured with Photonic Crystal Aggregates

Microstructural Periodic Arrays in Poly(Butylene Adipate) Featured with Photonic Crystal Aggregates

Temperature‐Responsive Photonic Devices Based on Cholesteric Liquid Crystals

Nanostructure-derived anti-reflectivity in leafhopper brochosomes

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