skip to content
Home

Yusuf Hamied Department of Chemistry

 

Professor Silvia Vignolini

Professor of Chemistry and Bio-materials

Photonic structures in Nature and Bio-mimetic Materials

Research Interests

Photonic structures in nature

Colour in nature is everywhere: animals and plants develop structures on sub-micrometer scale to manipulate light and to obtain brilliant and iridescent colours. This kind of colouration, named structural since it is not obtained using pigmentation, results from various mechanisms, including multilayered materials, crystalline inclusions and surface diffraction gratings. Pollia condensata fruits are one of the most striking examples of  strong iridescent colouration in plants. The colour is caused by Bragg-reflection of helicoidally stacked cellulose microfibrils, which form multilayers in the cell walls of the epicarp. The bright blue colour of this fruit is more intense than that of many previously described biological materials. Uniquely in nature, the reflected colour differs from cell to cell, as the layer thicknesses in the multilayer stack vary, giving the fruit a striking pixelated or ’pointillist’ appearance.

PNAS 109, 15712–15715, (2012)
 

Another striking example is the white of the Cyphochilus beetle which is native to South-East Asia, is whiter than paper, thanks to ultra-thin scales which cover its body. A new investigation of the optical properties of these scales has shown that they are able to scatter light more efficiently than any other biological tissue known, which is how they are able to achieve such a bright whiteness.

Scientific Reports 4, 6075 doi:10.1038/srep06075 (2014)

Funding

  1. BBSRC David Phillips fellowship
  2. Next Generation fellowship
  3. Isaac Newton Trust

Watch Professor Vignolini discuss her research

Take a tour of the Vignolini lab

Selected Publications

[1] Pointillist structural colour in Pollia fruit

S. Vignolini, P. J. Rudall, A. V. Rowland, A. Reed, E. Moyroud, R. B. Faden, J. J. Baumberg, B. J. Glover, U. Steiner; PNAS 109, 15712–15715, (2012). 

[2] Controlled bio-inspired self-assembly of cellulose-based chiral reflectors 

A. G. Dumanli, G. Kamita, J. Landman, H. van der Kooij, B. J. Glover, J. J. Baumberg, U Steiner, S. Vignolini;  Adv. Opt. Mat. DOI: 10.1002/adom.201400112  (2014)
 

[3]Bright-White Beetle scales Optimise Multiple Scattering of Light

M. Burresi, L. Cortese, L. Pattelli, M. Kolle, P.Vukusic, D. Wiersma, U. Steiner, and S.Vignolini; Scientific Reports 4, 6075 doi:10.1038/srep06075 (2014)

 

Publications

Tuning of photonic crystal cavities by controlled removal of locally infiltrated water
F Intonti, S Vignolini, F Riboli, M Zani, DS Wiersma, L Balet, LH Li, M Francardi, A Gerardino, A Fiore, M Gurioli
– Applied Physics Letters
(2009)
95,
173112
(doi: 10.1063/1.3247894)
Polarization-sensitive near-field investigation of photonic crystal microcavities
S Vignolini, F Intonti, F Riboli, DS Wiersma, L Balet, LH Li, M Francardi, A Gerardino, A Fiore, M Gurioli
– Applied Physics Letters
(2009)
94,
163102
(doi: 10.1063/1.3118578)
Near-field imaging of coupled photonic-crystal microcavities
S Vignolini, F Intonti, M Zani, F Riboli, DS Wiersma, LH Li, L Balet, M Francardi, A Gerardino, A Fiore, M Gurioli
– Applied Physics Letters
(2009)
94,
151103
(doi: 10.1063/1.3107269)
Local nanofluidic light sources in silicon photonic crystal microcavities.
S Vignolini, F Riboli, F Intonti, M Belotti, M Gurioli, Y Chen, M Colocci, LC Andreani, DS Wiersma
– Physical review. E, Statistical, nonlinear, and soft matter physics
(2008)
78,
045603
(doi: 10.1103/physreve.78.045603)
Nonlinear optical tuning of photonic crystal microcavities by near-field probe
S Vignolini, F Intonti, L Balet, M Zani, F Riboli, A Vinattieri, DS Wiersma, M Colocci, L Li, M Francardi, A Gerardino, A Fiore, M Gurioli
– Applied Physics Letters
(2008)
93,
023124
(doi: 10.1063/1.2960259)
Spectral tuning and near-field imaging of photonic crystal microcavities
F Intonti, S Vignolini, F Riboli, A Vinattieri, DS Wiersma, M Colocci, L Balet, C Monat, C Zinoni, LH Li, R Houdré, M Francardi, A Gerardino, A Fiore, M Gurioli
– Physical Review B Condensed Matter and Materials Physics
(2008)
78,
041401
(doi: 10.1103/PhysRevB.78.041401)
Near-field mapping of quantum dot emission from single-photonic crystal cavity modes
F Intonti, S Vignolini, F Riboli, A Vinattieri, DS Wiersma, M Colocci, M Gurioli, L Balet, C Monat, LH Li, N Le Thomas, R Houdré, A Fiore, M Francardi, A Gerardino, F Roemer, B Witzigmann
– Physica E: Low-dimensional Systems and Nanostructures
(2008)
40,
1965
(doi: 10.1016/j.physe.2007.09.086)
Photons flow in liquid circuits
F Intonti, S Vignolini, M Colocci, DS Wiersma
– LASER FOCUS WORLD
(2007)
43,
69
(link to publication)
Rewritable photonic circuits
F Intonti, S Vignolini, V Türck, M Colocci, P Bettotti, L Pavesi, SL Schweizer, R Wehrspohn, D Wiersma
– Applied Physics Letters
(2006)
89,
211117
(doi: 10.1063/1.2392720)
Light propagation in tunable photonic materials
DS Wiersma, J Bertolotti, S Gottardo, F Intonti, S Mujumdar, R Sapienza, C Toninelli, S Vignolini
– Optics InfoBase Conference Papers
(2006)
thb1
(doi: 10.1364/meta.2006.thb1)
  • <
  • 20 of 21
  • >

Research Group

Research Interest Groups

Telephone number

01223 761490 (shared)

Email address

sv319@cam.ac.uk

College

Jesus College

    Study at Cambridge

    About the University

    Research at Cambridge