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Biomimicry for the fashion industry Short note by Giuliano Benelli

( benelli.giuliano@gmail.com)

Introduction Biomimicry ( or biomimetics) is the imitation of the models, systems, and elements of nature for

the purpose of solving complex human problems ( from Wikipedia). The term biomimetics was

introduced by Schmitt in the early 1960s; it comes from the word bios, meaning of life, and

mimesis, meaning to imitate. Biomimetics is an emerging science that emulates nature’s

strategies and patterns to direct product design, processes, and polizie as well as draws inspiration

from the living world. The word biomimicry appeared in 1982 and was generalized in 1997 by

Janine Benyus in the book Biomimicry: Innovation Inspired by Nature, where is defined as a “new

science that studies nature’s models and then imitates or takes inspiration from these designs and

processes to solve human problems”. Benyus suggests looking to Nature as a “Model, Measure,

and Mentor” and emphasizes sustainability as an objective of biomimicry. More

simply, Biomimicry is the way to generate innovation inspired by Nature.

Biomimicry could in principle be applied in many fields as a consequence of about 3.8 billion

years of nature development and about 30 million species. Biomimicry is not a new idea. In fact

since time immemorial, simple people and scientists have been watching and studied nature’s

best ideas and then imitates these designs and processes to find answers and solve many

situations in the human history. However in recent years biomimicry has been catched the eye of

designers and researchers to develop new ideas in a concept of sustainable.

Biomimicry brings nature and technology together to create exciting new fabrics that are smarter

and more sustainable. Some real results deriving from biomimicry are presented in ” 14 Smart

Inventions Inspired by Nature: Biomimicry” by Bloomberg.

Many innovative ideas have been derived by the observation of nature. As an example Leonardo

da Vinci applied biomimicry to the study of birds in the hope of enabling human flight; through

observation the anatomy and flight of birds he proposed notes and sketches of "flying machines" (

figure 1). These ideas, together the observations of pigeons in flight, inspired for the Wright

Brothers in craeting and Flying the first airplane in 1903 ( figure 2).

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Figure 1 - Drawing of Leonardo's flying machine Figure 2 - Flying machine of Wright Brothers in 1902

( https://it.wikipedia.org/wiki/Ornitottero) (https://it.wikipedia.org/wiki/Ornitottero)

An another classical example of biomimicry real application has been derived by the observation

of the lotus ( figure 3) and its leafs ( figure 4). The bumpy surface of a lotus leaf acts as a self-

cleaning mechanism: dirt is cleansed off the surface naturally by water, for instance, during a rain

shower. Even the smallest of breezes on the plant causes a subtle shift in the angle of the plant

allowing gravity to remove the dirt without the plant having to expend any energy. The lotus leaf

has a series of protrusions on the order of 10 μm (1.0 x 10- 5 m) high covering its surface; each

protrusion is itself covered in bumps of a hydrophobic, waxy material that are roughly 100 nm (1 x

10-7 m) in height. When water droplets are applied to the lotus leaf, they sit lightly on the tips of

the hydrophobic protrusions as if on a bed of nails (see Figure 5). This same idea has been applied

to the design of new building materials such as paints, tiles, textiles, and glass that reduce the

need for detergents and also reduces maintenance and material replacement costs. A typical

example is the eco-friendly house paint called Lotusan, developed by the German company ISPO;

this exterior paint employs a microstructure modeled after the hydrophobic leaves of the lotus

plant to minimize the contact area for water and dirt ( figure 6).

Figure 3 – The lotus flower Figure 4 – The lotus leaf

( https://en.wikipedia.org/wiki/Lotus_effect)

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Figura 5. Computer-generated microscopic image of a lotus leaf with water droplets showing the

double structure of the leaf and the protrusions from the leaf covered in a rough, waxy material,

which creates its superhydrophobic surface ( image from

https://www.teachengineering.org/view_lesson.php?url=collection/duk_/lessons/duk_surfaceten

sionunit_lessons/duk_surfacetensionunit_less4.xml)

The self-cleaning and water-repellent qualities of superhydrophobic surfaces have the potential

for many practical applications.

Figure 6 – Lotusan product derived by observation of lotus behaviour and its utilization for self-

cleaning paint (http://jncc.defra.gov.uk/page-5592-theme=print )

Fashion and biomimicry

Biomimicry can support designers and producers of fashion apparel living inspirations when

developping their ranges. Biomimicry can support fashion industry to:

look in to nature for remodeling the fascinating innovations;

get interesting visual and aesthetic sense;

recreate visual and tactile textures.

In the following some simple and obvious examples of the biomimicry in the clopthing fashion are

briefly presented in figures 7, 8, 9 and 10.

Figure 7 - Sheep

Figure 9 – Bear

Some success stories of biomimicry in fashion

Velcro

Invented in 1948, Velcro has become a textbook example of biomimicry.

fast closing of garments, shoes, bags

between them with a simple pressure.

Mestral inspired by the small flowers

and 12). Analyzing them under the microscope

the summit a tiny hook, able to get stuck

observation it was implemented

furry fabric and equipped with many small

mechanism of "capture "observed in nature.

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Figure 8 - Whool

Figure 10 - Fur

of biomimicry in fashion

Invented in 1948, Velcro has become a textbook example of biomimicry. Velcro is a device for

, shoes, bags .... constituted by two strips of synthetic fabric

pressure. The idea was developed by the swiss engineer

small flowers that clung tightly to the fur of his dog du

under the microscope, de Mestral noticed that each petal

get stuck virtually wherever he found a foothold

it was implemented the Velcro strips composed by simple striped

many small hooks that attach securely to the slot

observed in nature.

Velcro is a device for

synthetic fabric that are joined

The idea was developed by the swiss engineer George de

during walks ( figure 11

each petal presented at

foothold natural. From this

striped nylon combined, a

to the slot, presenting the

Figure 11 - Tiny hooks covering the burr

https://goo.gl/5eCv1K

Figures 12 and 13 - Hook ( figure 1

Alexander Klink - Own work. Licensed under CC BY 3.0 via Commons

https://commons.wikimedia.org/wiki/File:Velcro_Loops.jpg#/media/File:Velcro_Loops.jpg

Figure 1

(https://it.wikipedia.org/wiki/Georges_de_Mestral#/media/File:Klettverschl

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Tiny hooks covering the burr Figure 12 - Burr

https://en.wikipedia.org/wiki/Bur

figure 12) and loops ( figure 13) in Velcro (

Own work. Licensed under CC BY 3.0 via Commons

https://commons.wikimedia.org/wiki/File:Velcro_Loops.jpg#/media/File:Velcro_Loops.jpg

Figure 14– An example of Velcro

https://it.wikipedia.org/wiki/Georges_de_Mestral#/media/File:Klettverschluss.jpg

https://en.wikipedia.org/wiki/Bur

) in Velcro ( "Velcro Loops" by

Own work. Licensed under CC BY 3.0 via Commons -

https://commons.wikimedia.org/wiki/File:Velcro_Loops.jpg#/media/File:Velcro_Loops.jpg).

uss.jpg

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Speedo Fastskin FSII swimsuit

The observation of the characteristics of skark skin ( figure 15) was the basis for the design of the

Fastskin FSII swimsuit. The shark skin seems composed by dermal denticles ( Figure 16) that

correspond to varying flow conditions.

Figure 15 – Shark Figure 16- Dermal dentique in a shark

(https://goo.gl/ahv1rk)

Rougher dermal dentice cover the nose of the animal, while smoother ones amass further back.

Furthermore, longitudinal grooves in the scales serve to channel water more efficiently over their

surface, enhancing thrust. Studies have been carried out first by George Lauder, a professor of

the Harvard University; Lauder will perform experiments to analyze the purpose of these dermal

denticles, and tested the Speedo suits as well, to see how similar they are.

Figure 17 - Speedo Fastskin swimsuit (http://www.swimming-faster.com/)

Morphotex

Morpho butterfly inspired Teijin Fibers Limited has made the world’s first structural chromogenic

fibers “ MORPHOTEX® ”. Morpho butterflies are colored in metallic, shimmering shades of blues

and greens; these colours are not a result of pigmentation but rather are an example of

iridescence through structural coloration. The scales on their wings are made of many layers of

proteins that refract light in different ways, and the color we see often is due entirely to the play

of light and structure rather than the presence of pigments. Teijin Fibers Limited of Japan

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produces Morphotex® fibers. No dyes or pigments are used. Rather, color is created based on the

varying thickness and structure of the fibers. Energy consumption and industrial waste are

reduced because no dye process must be used.

Figure 18 – Butterfly Morpheo Figure 19 - Dress Mimics Butterfly Wing shimmer

(https://goo.gl/uvzwM4) (http://goo.gl/NvZ4Bq)

Paramo’s waterproof jackets

Paramo’swaterproof jackets feature fabric technology was inspired by the transpiration activity of

trees. The process is similar to evaporation: pore-like openings in plant foliage, collectively known

as stomata,, composed by minute pores in the epidermis of the leaf or stem of a plant, forming a

slit of variable width that allows movement of gases in and out of the intercellular spaces.Leaf

stomata control plant CO2 absorption through photosynthesis and water loss through

transpiration. The water loss allows the plant to access carbon dioxide for photosynthesis, as well

as to cool itself when the mercury rises. Unlike conventional mineral wax, the company’s Nikwax

treatment leaves spaces between the fibers elastic, open, and breathable. Besides providing

water-repellency, the elastomer also traps air next to the skin, directing moisture away from the

body and preventing external moisture from entering

(http://sites.psu.edu/fbs5037/2015/04/05/blog-3-biomimicry-in-fashion/) .

Figures 20 and 21 - Paramo’s waterproof jackets

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These notes have been developed with the contribution of Silvia and Rose. A short note is

available also on the blog http://goo.gl/nuz5fn di La Maison Chic di Silvia. This note has been

realized starting from various documents and websites; some are listed below.

Some further readings

1. “Biomimetrics”, Wikipedia, https://en.wikipedia.org/wiki/Biomimetics

2. “Biomimicry”, Wikipedia, http://www.wikipedia.or.ke/index.php?title=Biomimicry

3. Biomimicry Institute, “What is Biomimicry”, http://biomimicry.org/what-is-

biomimicry/#.VoEL41lUy2o

4. Ask Nature , http://www.asknature.org/article/view/why_asknature

5. “How Biomimicry is inspiring human innovation”, Smithsonian.com

http://www.smithsonianmag.com/science-nature/how-biomimicry-is-inspiring-human-

innovation-17924040/?no-ist

6. “Fashionably Early Designing Australian Fashion Futures “, 9 August 2012, Conference,

https://www.academia.edu/4117306/Biomimicry_Fashion_Practice_pp.61-

70._Fashionable_Early_Conference_Aug_2012

7. “10 Eco-Fashion Garments Inspired by Nature and biomimicry”, Ecouterre,

http://www.ecouterre.com/10-eco-fashion-garments-inspired-by-nature-and-biomimicry/

8. “7 amazing examples of biomimicry”, mother nature network, http://www.mnn.com/earth-

matters/wilderness-resources/photos/7-amazing-examples-of-biomimicry/burr-velcro

9. “Nikwax Analogy”, Wikipedia, https://en.wikipedia.org/wiki/Nikwax_Analogy