Bio-inspired photonics

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Reef cuttlefish (a cephalopod) using dynamic camouflage to blend in to its surroundings.

Bio-inspired photonics or bio-inspired optical materials are the application of

biomimicry (the use of natural models, systems, and elements for human innovations[1]) to the field of photonics (the science and application of light generation, detection, and manipulation[2]). This differs slightly from biophotonics which is the study and manipulation of light to observe its interactions with biology.[3] One area that inspiration may be drawn from is structural color, which allows color to appear as a result of the detailed material structure.[4] Other inspiration can be drawn from both static and dynamic camouflage in animals like the chameleon[5] or some cephalopods.[6] Scientists have also been looking to recreate the ability to absorb light using molecules from various plants and microorganisms.[7] Pulling from these heavily evolved
constructs allows engineers to improve and optimize existing photonic technologies, whilst also solving existing problems within this field.

History

The microscope used by Robert Hooke to make the observations he made in the text Micrographia. It is displayed in the National Museum of Health and Medicine (Washington DC).

One of the earliest encounters with biological photonics was as early as the 6th century B.C.E (before common era). The Greek philosopher Anaximander, widely regarded as the first scientist, had a student named Anaximenes, who had the first documented mention of bioluminescence.[8][9] He described seeing a glow in the water when striking it with an oar.[10] Similarly, Aristotle also experienced the same phenomena, which he documented in works like Meteorologica[11] and De Coloribus.[12] He mentions seeing "things which are neither fire nor forms of fire seem to produce light by nature.[12]"

Although it was experienced that early, there was still no explanation to why it was occurring. It was not until the early microscopes, utilized by Robert Hooke in the mid-1600s,[13] that allowed humans to observe nature in greater detail. Hooke himself published what he had seen in the text Micrographia in 1665.[14] Here he describes various biological structures such as the feathers of colorful birds, wing and eyes of flies, and pearlescent scales of silverfish. This ability to look at the microstructures of nature, gave scientists information on the mechanisms behind the interactions between biology and light. The Theorie of Imperfection, published by the Russian biophysicist Zhuralev and American biochemist Seliger, is the first working hypothesis about the ultra-weak emission of photons by biological systems.[15] Further developments in microscopy, like scanning electron microscopy (SEM),[16] only increased this and would allow scientists to mimic these observed structures.

In addition, the concept of biomimicry was spurred by many scientists, including Leonardo da Vinci. He spent a great deal of time studying the anatomy of birds and their flight capabilities. As demonstrated by various sketches and notes he left behind, he even attempted to create a "flying machine".[17] Although unsuccessful, it was one of the earliest examples of biomimicry.

Dinoflagellate (a type of marine plankton) bioluminescence in sea water when agitated by waves
A drawing from Leonardo da Vinci for a theorized "flying machine" to mimic the flight of birds

Molecular biomimetics

Molecular biomimetics involves the design of optical materials based on specific molecules and/or macromolecules to induce coloration.[18] Molecularly Imprinted Polymers (MIPs) are specifically aimed at sensing macromolecules.[19] They can also form them into specific structures that change color.[20] Pigment-inspired materials aiming for specific molecular light absorption have been developed as for example melanin-inspired films prepared by polymerization of melanin precursors such as dopamine and 5,6-dihydroxyindole to provoke color saturation.[21][22][23]

transparent wood and paper.[35][36] Pressure and solvent polarity affect the color of a manufactured cellulose membrane, to the point of detection by the naked eye. Cellulose can also be used as nanofibrils or nanocrystals after treatments. One such treatment involves a nitrating agent to form nitrocellulose.[20] Cellulose nanocrystals can polarize light.[37]

Bioinspired periodic/aperiodic structures

Main article: structural coloration

Structural color is a type of coloration that arises from the interaction of light with nano-sized structures.[38] This interaction is possible because these photonic structures are of the same size as the wavelength of light. Through a mechanism of constructive and destructive interference, certain colors get amplified, while others diminish.

Photonic structures are abundant in nature, existing in a wide range of organisms. Different organisms use different structures, each with a different morphology designed to obtain the desired effect. Examples of this are the photonic crystal underlying the bright colors in peacock feathers[39] or the tree-like structures responsible for the bright blue in some Morpho butterflies.[40]

An example of bio-inspired photonics using structures is the so-called moth eye. Moths have a structure of ordered cylinders in their eyes that do not produce color, but instead reduce reflectivity.[41] This concept has led to creation of antireflective coatings.[42]

A combination of chemical structure and how it interacts with visible light creates color within organisms' nature.[4] The creation of specific biological photonics requires identifying the chemical components of the structure, the optical response created by the physics and the structure's function.[20] The complex structures created by nature can range from simple, quasi-ordered structures to hierarchical complex formations.[4]

2-D Structures

Simple Array Structure (Peacock Feathers)

Nature sometimes manipulates the nanostructure, such as its crystal lattice parameters in order to create its patterns and colors.[20][43][44][45][46] The Barbule (the individual strands of a feather that hold its color) of the peacock is made of an outer layer of keratin and an inner layer containing an array of melanin rods connected by keratin with holes separating them. When the melanin rods are parallel to the lattice arrangement of the structure of the keratin outer layer it creates the brown color. The rest of the colors of the feather are created by changing the spacing of the melanin layers.[20][47][48][49]

Multiple types of structures present in bio photonics

Aperiodic Photonic Structures

Aperiodic Photonic Structures do not have a unit cell and are capable of creating band gaps without the requirement of a high index of refraction difference. Also known as quasi-ordered crystal structure creates blue and green coloring.[20]

3-D Structures

Helicoidal Multilayers

These are twisted multilayers where fibers are aligned in the same direction and each layer they are slightly rotated.[50][51] This structure allows nature to reflect polarized light and creates an intense value due to Bragg reflection.[4][20][51]

Application Examples

Bioinspired antibacterial structural color hydrogel

As a form of application, biophotonics are used in order to indicate antibacterial and self-healing properties. Since the existence of silver nanoparticles prevent bacterial adhesion (there is already bacteria existing in the hydrogel) it causes hydrogel degradation and color fading. This allows for the engineered hydrogel to display with color its integrity after self-healing.[4][52]

Photonic nanoarchitectures in butterflies and beetles

Nanoarchitectures contribute to the iridescence of butterflies and beetles. Multilayers are common, typically in a 1-D or 3-D structure, 2-D structures are more rare.[53] Disorder and irregularity in the structure are “intentional” and adapted to the habitat. The structure has been successfully recreated and can be used as a coating.[54] It is also used in some applications where stable, vibrant color is required. It is flexible enough that it can be designed to have a pattern.[55] 

Mimicking fireflies to improve LED efficiency

When observing fireflies (Photuris sp.) using SEM, it was observed that their light emitting cuticle had a specific 2D periodic structure. It is structured following a “factory roof” like pattern with scales oriented at a tilted slope and a sharp edge on the protruding side of the scales.[56][57] When modeling a similar structure using a photoresist layer on light emitting diodes (LEDs), it resulted in a 68% power increase and 55% increase in light extraction efficiency (LEE). This technology reduces the amount of energy consumed to produce the same amount of light.[58]

Responsive materials

Responsive materials are materials or devices that can respond to external stimuli as they occur. A little bit of time is taken to adjust to the new surroundings, but the idea remains consistent with what is seen in nature. The most commonly used examples are the chameleon or octopus, as their responsive skin allows them to change the color or even the texture of their skin.[59] The mechanisms behind these tactics are called chromatophores, which are pigment-filled sacs that uses muscles and nerves to change the animal's external appearance. These chromatophores are activated by neuronal activity, so an animal can change its color just by thinking about it.[60] The animal uses another mechanism to be able to know what color or shape to take; a photo-sensitive cell within their skin called opsin is able to detect light (and possibly color). The animal can use these opsins to their advantage to quickly assess their surroundings, before turning on their chromatophores to accurately camouflage to their circumstances.

A lot of creatures have camouflage incorporated into their bodies — take the fish in the figure on the right for example. In this hypothetical, the animal can appear in two different ways depending on their surroundings: in the middle of the ocean away from all solid objects, it can appear near-translucent; near the sea floor where potential predators will only sense it from above, it can turn darker to naturally blend in with the rocky bottom. Many fish, such as the marine hatchetfish, use a combination of camouflage techniques to achieve these appearances.

Silvering, a common tactic, utilizes highly reflective scales to reflect the surrounding light effectively enough to make the scales appear invisible from the side. Counterillumination
, a tactic used more by deep-sea dwellers, uses a luminous organ located in the bottom of the body to emit light in order to appear brighter from underneath. At this angle, the light emitted is at an intensity meant to replicate the sunlight as it appears on the surface of the water. Thus, from below the creature is essentially invisible to many predators.

Within the luminous organ is a laminar structure of photocytes and nerve branches, with relatively small gap junctions between them.[62] It is thought that the vast interconnectivity and the layered structure of these neuro-photocyte units is what allows a deep-sea fish to rapidly respond to a situation with spontaneous luminescence. Because all of the nerves are directly connected to the spinal cord (and by extension, the brain), researchers believe that electronic signals can trigger these photocytes to react.[63] With this line of thinking, scientists are working to develop technology using this type of neuro-photocyte unit.

These biologically inspired materials can be applied in many different circumstances.[64] This technology can be used to camouflage objects, create a device that can mold its shape yet still retain its desired properties, or even help people in relation to biomedical applications. A coating of this technology can help incorporate a foreign body into a living ecosystem, i.e. a human body. The technology of this device allows a person's antibodies to detect the new object as a non-threat, thus permitting easier acceptance of manmade tools into the body, such as a cardiac pacing device to the chest.

References

  1. OCLC 880809097
    .
  2. ISBN 978-0-471-79158-4
    .
  3. OCLC 748773038
    .
  4. ^
    OCLC 963587905
    .
  5. S2CID 244222072
    .
  6. PMID 19008200
    .
  7. PMID 20446691
    .
  8. OCLC 497860307
    .
  9. doi:10.17516/1997-1389-0264
    .
  10. OCLC 18853022
    .
  11. OCLC 875239302
    .
  12. ^ a b Aristotle. Philoponus J, Kupreeva I (eds.). "De Coloribus". penelope.uchicago.edu. Retrieved 2022-04-28.
  13. PMID 27017680
    .
  14. ^ Hooke R, Martyn J, Allestry J, Lessing J (1665). Micrographia: or, Some physiological descriptions of minute bodies made by magnifying glasses: With observations and inquiries thereupon. London: Printed by Jo. Martyn, and Ja. Allestry, Printers to the Royal Society, and are to be sold at their Shop at the Bell, in S. Paul's Church-yard – via Rosenwald Collection (Library of Congress).
  15. ^ "Origins of biophotonics".
  16. PMID 21483100
    .
  17. OCLC 213812382
    .
  18. ^
    PMID 28937748
    .
  19. PMID 28626651
    .
  20. ^
    S2CID 225225204
    .
  21. PMID 25938924
    .
  22. PMID 25224565
    .
  23. PMID 22044029
    .
  24. PMID 22024699
    .
  25. ISSN 1528-7483
    .
  26. PMID 25757068
    .
  27. S2CID 44490101
    .
  28. PMID 17546036
    .
  29. PMID 25853731
    .
  30. S2CID 27851918
    .
  31. PMID 23015522
    .
  32. S2CID 138648401
    .
  33. S2CID 18005260
    .
  34. PMID 15861454
    .
  35. PMID 29277747
    .
  36. S2CID 135759478
    .
  37. S2CID 139124385
    .
  38. S2CID 53068819
    .
  39. PMID 14557541
    .
  40. ISSN 0002-9505
    .
  41. S2CID 4219431
    .
  42. ISSN 0927-796X
    .
  43. ISSN 0030-3992
    .
  44. S2CID 45160958
    .
  45. S2CID 122619039
    .
  46. S2CID 122802565
    .
  47. PMID 23698284
    .
  48. ISSN 1465-7279
    .
  49. PMID 16089929
    .
  50. ISSN 0079-6425
    .
  51. ^
    PMID 23019355
    .
  52. PMID 29027783
    .
  53. S2CID 126635261
    .
  54. S2CID 53350911
    .
  55. PMID 34557736
    .
  56. S2CID 122030956
    .
  57. S2CID 119844791
    .
  58. S2CID 207325249
    .
  59. PMID 35347207
    .
  60. ^ Courage, Katherine Harmon (August 21, 2014). "Octopus-Inspired Camouflage Flashes To Life In Smart Material". Scientific American Blog Network. Retrieved 2022-04-29.
  61. S2CID 232262198
    .
  62. PMID 857636
    .
  63. doi:10.1111/j.0022-1112.2004.00410.x
    .
  64. S2CID 228099758
    .
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