Biomedical Engineering Reference
In-Depth Information
of regularity and irregularity in an iridescent scale,
Proc
R Soc Lond B
269
(2002), 1417-1421.
[28] A. Saito, Y. Miyamura, Y. Ishikawa, K. Sogo, Y. Kuwa-
hara, and Y. Hirai, Reproduction of the
Morpho
blue by
nanocasting lithography,
J Vac Sci Technol B
24
(2006),
3248-3251.
[29] A. Saito, Y. Miyamura, Y. Ishikawa, J. Murase,
M. Akai-Kasaya, and Y. Kuwahara, Reproduction,
mass-production, and control of the Morpho-butter-
fly's blue,
Proc SPIE
7205
(2009), 720506.
[30] P. Vukusic and J.R. Sambles, Photonic structures in
biology,
Nature
424
(2003), 852-855.
[31] P. Vukusic, J.R. Sambles, and C.R. Lawrence, Structur-
ally assisted blackness in butterfly scales,
Proc R Soc
Lond B
271
(2004), S237-S239.
[32] P. Vukusic and I. Hooper, Directionally controlled fiuo-
rescence emission in butterflies,
Science
310
(2005), 1151.
[33] P. Vukusic, B. Hallam, and J. Noyes, Brilliant white-
ness in ultrathin beetle scales,
Science
315
(2007), 348.
[34] A.R. Parker, Z. Hegedus, and R.A. Watt, Solar-absorber
antireflector on the eye of an Eocene fly, [45 Ma],
Proc
R Soc Lond B
265
(1998), 811-815.
[35] A.R. Parker, A vision for natural photonics,
Phil Trans
R Soc Lond A
362
(2004), 2709-2720.
[36] A.R. Parker and H.E. Townley, Biomimetics of pho-
tonic nanostructures,
Nat Nanotechnol
[45] J. Huang, X. Wang, and Z.L. Wang, Controlled replica-
tion of butterfly wings for achieving tunable photonic
properties,
Nano Lett
6
(2006), 2325-2331.
[46] J. Silver, R. Withnall, T.G. Ireland, G.R. Fern, and S. Zhang,
Light-emitting nanocasts formed from bio-templates:
FESEM and cathodoluminescent imaging studies of but-
terfly scale replicas,
Nanotechnology
19
(2008), 095302.
[47] G. Zhang, J. Zhang, G. Xie, Z. Liu, and H. Shao, Cicada
wings: a stamp from nature for nanoimprint lithogra-
phy,
Small
2
(2006), 1440-1443.
[48] R.J. Martín-Palma, C.G. Pantano, and A. Lakhtakia,
Biomimetization of butterfly wings by the conformal-
evaporated-film-by-rotation technique for photonics,
Appl Phys Lett
93
(2008), 083901.
[49] M. Srinivasarao, Nano-optics in the biological world:
beetles, butterflies, birds, and moths,
Chem Rev
99
(1999), 1935-1961.
[50] H. D. Wolpert, Optical filters in nature,
OSA Opt Photon
News
20
(2) (February 2009), 22-27,
http://www.
osa-opn.org
(accessed 12 March 2013).
[51] C.W. Mason, Structural colors in feathers. I,
J Phys
Chem
27
(1923), 201-251.
[52] C.F. Bohren and D.R. Huffman,
Absorption and scattering
of light by small particles
, Wiley, New York, NY, USA
(1983).
[53] R.J. Martín-Palma and A. Lakhtakia,
Nanotechnology: a
crash course
, SPIE Press, Bellingham, WA, USA (2010).
[54] J.D. Joannopoulos, R.D. Meade, and J.N. Winn,
Pho-
tonic Crystals
, Princeton University Press, Princeton,
NJ, USA (1995).
[55] E. Adachi and K. Matsubara, Reproducibility and
applicability of gallium replication as evaluated by
biological specimen use,
J Electron Microsc
49
(2000),
371-378.
[56] H.C. Bolton, L.A. Bursill, A.C. McLaren, and R.G.
Turner, On the origin of the colour of labradorite,
phys
stat sol (b)
18
(1966), 221-230.
[57] Y. Miura, T. Tomisaka, and T. Kato, Experimental and
theoretical approaches to iridescent labradorite,
Mem
Geol Soc Jap
11
(1974), 145-165.
[58] R. Velázquez-Castillo, J. Reyes-Gasga, D.I. García-
Gutierrez, and M. Jose-Yacaman, Nanoscale charac-
terization of nautilus shell structure: an example of
natural self-assembly,
J Mater Res
2
(2007),
347-353.
[37] J.P. Vigneron, J.M. Pasteels, D.M. Windsor, Z. Vértesy,
M. Rassart, T. Seldrum, J. Dumont, O. Deparis,V. Lousse,
L.P. Biró, D. Ertz, and V. Welch, Switchable reflector in the
Panamanian tortoise beetle
Charidotel laegregia
(Chrysomel-
idae: Cassidinae),
Phys Rev E
76
(2007), 031907.
[38] K. Michielsen and D.G. Stavenga, Gyroid cuticular
structures in butterfly wing scales: biological photonic
crystals,
J R Soc Interf
5
(2008), 85-94.
[39] J.W. Galusha, L.R. Richey, J.S. Gardner, J.N. Cha, and
M.H. Bartl, Discovery of a diamond-based photonic
crystal structure in beetle scales,
Phys Rev E
77
(2008),
050904.
[40] O. Sato, S. Kubo, and Z.-Z. Gu, Structural color films
with Lotus effects, superhydrophilicity, and tunable
stop- bands,
Acc Chem Res
42
(2009), 1-10.
[41] S. Kinoshita and S. Yoshioka (eds.),
Structural colors in
biological systems: principles and applications
, Osaka Uni-
versity Press, Osaka, Japan (2005).
[42] A. Parker,
Seven deadly colours: the genius of nature's
palette and how it eluded Darwin
, Free Press, New York,
NY, USA (2006).
[43] A. I. Ingram, Butterfly photonics: form and function,
in
Functional surfaces in biology, Vol. 1: Little structures
with big effects
(S. N. Gorb, ed.), Springer-Verlag, Hei-
delberg, Germany (2009).
loreala_sofcolor.aspx
(accessed 1 February 2013).
21
(2006),
1484-1489.
[59] M.S. Giridhar and S.K. Srivatsa, Pearls and shells,
Curr
Sci
76
(1999), 1324-1325.
[60] K. Lyman (ed.),
Simon & Schuster's guide to gems and
precious stones
, Simon & Schuster, New York, NY, USA
(1986).
[61] A.E. Seago, P. Brady, J.-P. Vigneron, and T.D. Schultz,
Gold bugs and beyond: a review of iridescence and
structural colour mechanisms in beetles (Coleoptera),
J R Soc Interf
6
(2009), S165-S184.
