Structural Coloration in Textiles

Antoacutenio Pedro Souto Andrea ZilleDepartamento de Engenharia Tecircxtil

Universidade do Minho Portugalsoutodetuminhopt

Porto 13 de fevereiro de 2017

Gonul YavuzEge University Textile and

Apparel Research and Application Centerİzmir Turkey

doi103390s130404192

Photonic crystals

DOI 101515nanoph-2013-0015

Photonic Crystals 1DMorpho butterfly

doi 101098rspb20022019

Photonic Crystals 1DMorpho butterfly

200 nm

Lamellar structure in 6 - 8 layers

The pigmentationin the scale absorbs the extraneous green to redlight and enhances the blue colouring

Photonic Crystals 2DMallard duck

doi101038srep04718

Photonic Crystals 3D diamond-based structure in the beetle

L augustus

httpsdoiorg101103PhysRevE77050904

httpphysicsbuzzphysicscentralcom2008_05_01_archivehtml

Photonic Crystals 3D diamond-based structure in

the beetle L augustus

httpsdoiorg101103PhysRevE77050904

httpphysicsbuzzphysicscentralcom2008_05_01_archivehtml

F Liu B Q Dong X H Liu Y M Zheng J Zi Structural color change in longhorn beetles Tmesisternus isabellae Opt Express 17 16183-16191 (2009) httpswwwosapublishingorgoeabstractcfmuri=oe-17-18-16183

Sensors made of Photonic crystals

httpcdniopsciencecomimages0957-44842712122001Fullnanoaa13e1f8_lrjpg

- by humidity effect

Photonic Crystals 3D beetle Tmesisternus isabellae

Photonic Crystals 1DMorpho butterfly

- at our lab

- wet - drying

DOI 101515nanoph-2013-0015

Photonic Crystals 1DMorpho butterfly

doi 101098rspb20022019

Photonic Crystals 1DMorpho butterfly

200 nm

Lamellar structure in 6 - 8 layers

The pigmentationin the scale absorbs the extraneous green to redlight and enhances the blue colouring

Photonic Crystals 2DMallard duck

doi101038srep04718

Photonic Crystals 3D diamond-based structure in the beetle

L augustus

httpsdoiorg101103PhysRevE77050904

httpphysicsbuzzphysicscentralcom2008_05_01_archivehtml

Photonic Crystals 3D diamond-based structure in

the beetle L augustus

httpsdoiorg101103PhysRevE77050904

httpphysicsbuzzphysicscentralcom2008_05_01_archivehtml

F Liu B Q Dong X H Liu Y M Zheng J Zi Structural color change in longhorn beetles Tmesisternus isabellae Opt Express 17 16183-16191 (2009) httpswwwosapublishingorgoeabstractcfmuri=oe-17-18-16183

Sensors made of Photonic crystals

httpcdniopsciencecomimages0957-44842712122001Fullnanoaa13e1f8_lrjpg

- by humidity effect

Photonic Crystals 3D beetle Tmesisternus isabellae

Photonic Crystals 1DMorpho butterfly

- at our lab

- wet - drying

doi 101098rspb20022019

Photonic Crystals 1DMorpho butterfly

200 nm

Lamellar structure in 6 - 8 layers

The pigmentationin the scale absorbs the extraneous green to redlight and enhances the blue colouring

Photonic Crystals 2DMallard duck

doi101038srep04718

Photonic Crystals 3D diamond-based structure in the beetle

L augustus

httpsdoiorg101103PhysRevE77050904

httpphysicsbuzzphysicscentralcom2008_05_01_archivehtml

Photonic Crystals 3D diamond-based structure in

the beetle L augustus

httpsdoiorg101103PhysRevE77050904

httpphysicsbuzzphysicscentralcom2008_05_01_archivehtml

F Liu B Q Dong X H Liu Y M Zheng J Zi Structural color change in longhorn beetles Tmesisternus isabellae Opt Express 17 16183-16191 (2009) httpswwwosapublishingorgoeabstractcfmuri=oe-17-18-16183

Sensors made of Photonic crystals

httpcdniopsciencecomimages0957-44842712122001Fullnanoaa13e1f8_lrjpg

- by humidity effect

Photonic Crystals 3D beetle Tmesisternus isabellae

Photonic Crystals 1DMorpho butterfly

- at our lab

- wet - drying

Photonic Crystals 2DMallard duck

doi101038srep04718

Photonic Crystals 3D diamond-based structure in the beetle

L augustus

httpsdoiorg101103PhysRevE77050904

httpphysicsbuzzphysicscentralcom2008_05_01_archivehtml

Photonic Crystals 3D diamond-based structure in

the beetle L augustus

httpsdoiorg101103PhysRevE77050904

httpphysicsbuzzphysicscentralcom2008_05_01_archivehtml

F Liu B Q Dong X H Liu Y M Zheng J Zi Structural color change in longhorn beetles Tmesisternus isabellae Opt Express 17 16183-16191 (2009) httpswwwosapublishingorgoeabstractcfmuri=oe-17-18-16183

Sensors made of Photonic crystals

httpcdniopsciencecomimages0957-44842712122001Fullnanoaa13e1f8_lrjpg

- by humidity effect

Photonic Crystals 3D beetle Tmesisternus isabellae

Photonic Crystals 1DMorpho butterfly

- at our lab

- wet - drying

Photonic Crystals 3D diamond-based structure in the beetle

L augustus

httpsdoiorg101103PhysRevE77050904

httpphysicsbuzzphysicscentralcom2008_05_01_archivehtml

Photonic Crystals 3D diamond-based structure in

the beetle L augustus

httpsdoiorg101103PhysRevE77050904

httpphysicsbuzzphysicscentralcom2008_05_01_archivehtml

F Liu B Q Dong X H Liu Y M Zheng J Zi Structural color change in longhorn beetles Tmesisternus isabellae Opt Express 17 16183-16191 (2009) httpswwwosapublishingorgoeabstractcfmuri=oe-17-18-16183

Sensors made of Photonic crystals

httpcdniopsciencecomimages0957-44842712122001Fullnanoaa13e1f8_lrjpg

- by humidity effect

Photonic Crystals 3D beetle Tmesisternus isabellae

Photonic Crystals 1DMorpho butterfly

- at our lab

- wet - drying

Photonic Crystals 3D diamond-based structure in

the beetle L augustus

httpsdoiorg101103PhysRevE77050904

httpphysicsbuzzphysicscentralcom2008_05_01_archivehtml

F Liu B Q Dong X H Liu Y M Zheng J Zi Structural color change in longhorn beetles Tmesisternus isabellae Opt Express 17 16183-16191 (2009) httpswwwosapublishingorgoeabstractcfmuri=oe-17-18-16183

Sensors made of Photonic crystals

httpcdniopsciencecomimages0957-44842712122001Fullnanoaa13e1f8_lrjpg

- by humidity effect

Photonic Crystals 3D beetle Tmesisternus isabellae

Photonic Crystals 1DMorpho butterfly

- at our lab

- wet - drying

F Liu B Q Dong X H Liu Y M Zheng J Zi Structural color change in longhorn beetles Tmesisternus isabellae Opt Express 17 16183-16191 (2009) httpswwwosapublishingorgoeabstractcfmuri=oe-17-18-16183

Sensors made of Photonic crystals

httpcdniopsciencecomimages0957-44842712122001Fullnanoaa13e1f8_lrjpg

- by humidity effect

Photonic Crystals 3D beetle Tmesisternus isabellae

Photonic Crystals 1DMorpho butterfly

- at our lab

- wet - drying

doi103390s130404192 DOI 101002adma201202459DOI 101021nl061580m

Sensors made of Photonic crystals - by temperature effect - by chemical effect

- by pH effect- others

ionic species

pressure

biomolecules

In air

In ethanol

Lab preparationldquosoap-free emulsion polymerizationrdquo

Monodispersed composite latex spheres of poly-(styrene-methyl methacrylate-acrylic acid) (P(St-

MMA-AA)) were synthesized by soap-free emulsion polymerization in a three-necked flask

equipped with a reflux condenser and a mechanical stirrer

The mixture was stirred at 70 degC in N2atmosphere for 5 h to obtain a homogeneous

particle diameter of sim380 nm

Nanophotonic Crystals Size Control parametersTo make larger spheres

a use a bigger concentration of monomer

b use a lower temperature or

c use less initiator

Momodisperse (P(St-MMA-AA)) poly-(styrene-methylmethacrylate-acrylic acid)

Nano-photonic crystals were applied by

-Deposition method

Structural Coloration on Textiles

Black cotton fabric coated with vertical

deposition self asembly

httpwwwasknatureorgstrategy1d00d97a206855365c038d57832ebafa

Color without pigmentdyes on fabric

by applying a coating with nanophotonic crystals

Structural Coloration on Textiles

Lab preparationldquosoap-free emulsion polymerizationrdquo

Monodispersed composite latex spheres of poly-(styrene-methyl methacrylate-acrylic acid) (P(St-

MMA-AA)) were synthesized by soap-free emulsion polymerization in a three-necked flask

equipped with a reflux condenser and a mechanical stirrer

The mixture was stirred at 70 degC in N2atmosphere for 5 h to obtain a homogeneous

particle diameter of sim380 nm

Nanophotonic Crystals Size Control parametersTo make larger spheres

a use a bigger concentration of monomer

b use a lower temperature or

c use less initiator

Momodisperse (P(St-MMA-AA)) poly-(styrene-methylmethacrylate-acrylic acid)

Nano-photonic crystals were applied by

-Deposition method

Structural Coloration on Textiles

Black cotton fabric coated with vertical

deposition self asembly

httpwwwasknatureorgstrategy1d00d97a206855365c038d57832ebafa

Color without pigmentdyes on fabric

by applying a coating with nanophotonic crystals

Structural Coloration on Textiles

Nanophotonic Crystals Size Control parametersTo make larger spheres

a use a bigger concentration of monomer

b use a lower temperature or

c use less initiator

Momodisperse (P(St-MMA-AA)) poly-(styrene-methylmethacrylate-acrylic acid)

Nano-photonic crystals were applied by

-Deposition method

Structural Coloration on Textiles

Black cotton fabric coated with vertical

deposition self asembly

httpwwwasknatureorgstrategy1d00d97a206855365c038d57832ebafa

Color without pigmentdyes on fabric

by applying a coating with nanophotonic crystals

Structural Coloration on Textiles

Momodisperse (P(St-MMA-AA)) poly-(styrene-methylmethacrylate-acrylic acid)

Nano-photonic crystals were applied by

-Deposition method

Structural Coloration on Textiles

Black cotton fabric coated with vertical

deposition self asembly

httpwwwasknatureorgstrategy1d00d97a206855365c038d57832ebafa

Color without pigmentdyes on fabric

by applying a coating with nanophotonic crystals

Structural Coloration on Textiles

Black cotton fabric coated with vertical

deposition self asembly

httpwwwasknatureorgstrategy1d00d97a206855365c038d57832ebafa

Color without pigmentdyes on fabric

by applying a coating with nanophotonic crystals

Structural Coloration on Textiles

Structural Coloration on

Textiles

Applying Nano-photonics Crystals to Textile

bull How to improve washing durability

A study is going on to improve washing fastness without loosing the handle properties applying mixture of polymers

Nowadays challenges

bull Can we give to the Nanophotonic crystals colour

YES WE CAN

bull Can we ldquoworkrdquo with several layers of color

YES WE CAN

-gt We have done it

Nowadays challenges

Nowadays challenges

1 It is possible to obtain color using nanophotoniccrystals

2 Nanophotonic crystals can be applied to textiles

3 It is possible to increase washing fastness of thesecolorful systems

4 Structural coloring is an innovative and ecologicaltechnology which can reduce the environmentalimpact of traditional coloring processes

Conclusion

The authors would like to express their acknowledgment to the organizers of

iTechStylesummit

International Conference on Textiles amp Clothing

Thank you for your attention

Dep Engenharia Tecircxtil

Antoacutenio Pedro Garcia de Valadares SoutoUniversidade do Minho Guimaratildees Portugal

Departamento de Engenharia Tecircxtilsoutodetuminhopt

Applying Nano-photonics Crystals to Textile

bull How to improve washing durability

A study is going on to improve washing fastness without loosing the handle properties applying mixture of polymers

Nowadays challenges

bull Can we give to the Nanophotonic crystals colour

YES WE CAN

bull Can we ldquoworkrdquo with several layers of color

YES WE CAN

-gt We have done it

Nowadays challenges

Nowadays challenges

1 It is possible to obtain color using nanophotoniccrystals

2 Nanophotonic crystals can be applied to textiles

3 It is possible to increase washing fastness of thesecolorful systems

4 Structural coloring is an innovative and ecologicaltechnology which can reduce the environmentalimpact of traditional coloring processes

Conclusion

The authors would like to express their acknowledgment to the organizers of

iTechStylesummit

International Conference on Textiles amp Clothing

Thank you for your attention

Dep Engenharia Tecircxtil

Antoacutenio Pedro Garcia de Valadares SoutoUniversidade do Minho Guimaratildees Portugal

Departamento de Engenharia Tecircxtilsoutodetuminhopt

Nowadays challenges

bull Can we give to the Nanophotonic crystals colour

YES WE CAN

bull Can we ldquoworkrdquo with several layers of color

YES WE CAN

-gt We have done it

Nowadays challenges

Nowadays challenges

1 It is possible to obtain color using nanophotoniccrystals

2 Nanophotonic crystals can be applied to textiles

3 It is possible to increase washing fastness of thesecolorful systems

4 Structural coloring is an innovative and ecologicaltechnology which can reduce the environmentalimpact of traditional coloring processes

Conclusion

The authors would like to express their acknowledgment to the organizers of

iTechStylesummit

International Conference on Textiles amp Clothing

Thank you for your attention

Dep Engenharia Tecircxtil

Antoacutenio Pedro Garcia de Valadares SoutoUniversidade do Minho Guimaratildees Portugal

Departamento de Engenharia Tecircxtilsoutodetuminhopt

Nowadays challenges

Nowadays challenges

1 It is possible to obtain color using nanophotoniccrystals

2 Nanophotonic crystals can be applied to textiles

3 It is possible to increase washing fastness of thesecolorful systems

4 Structural coloring is an innovative and ecologicaltechnology which can reduce the environmentalimpact of traditional coloring processes

Conclusion

The authors would like to express their acknowledgment to the organizers of

iTechStylesummit

International Conference on Textiles amp Clothing

Thank you for your attention

Dep Engenharia Tecircxtil

Antoacutenio Pedro Garcia de Valadares SoutoUniversidade do Minho Guimaratildees Portugal

Departamento de Engenharia Tecircxtilsoutodetuminhopt

Nowadays challenges

1 It is possible to obtain color using nanophotoniccrystals

2 Nanophotonic crystals can be applied to textiles

3 It is possible to increase washing fastness of thesecolorful systems

4 Structural coloring is an innovative and ecologicaltechnology which can reduce the environmentalimpact of traditional coloring processes

Conclusion

The authors would like to express their acknowledgment to the organizers of

iTechStylesummit

International Conference on Textiles amp Clothing

Thank you for your attention

Dep Engenharia Tecircxtil

Antoacutenio Pedro Garcia de Valadares SoutoUniversidade do Minho Guimaratildees Portugal

Departamento de Engenharia Tecircxtilsoutodetuminhopt

1 It is possible to obtain color using nanophotoniccrystals

2 Nanophotonic crystals can be applied to textiles

3 It is possible to increase washing fastness of thesecolorful systems

4 Structural coloring is an innovative and ecologicaltechnology which can reduce the environmentalimpact of traditional coloring processes

Conclusion

The authors would like to express their acknowledgment to the organizers of

iTechStylesummit

International Conference on Textiles amp Clothing

Thank you for your attention

Dep Engenharia Tecircxtil

Antoacutenio Pedro Garcia de Valadares SoutoUniversidade do Minho Guimaratildees Portugal

Departamento de Engenharia Tecircxtilsoutodetuminhopt

The authors would like to express their acknowledgment to the organizers of

iTechStylesummit

International Conference on Textiles amp Clothing

Thank you for your attention

Dep Engenharia Tecircxtil

Antoacutenio Pedro Garcia de Valadares SoutoUniversidade do Minho Guimaratildees Portugal

Departamento de Engenharia Tecircxtilsoutodetuminhopt