Interference is the source of some of the spectacular colors of animals and plants in nature. In some of these systems, the physical structure consists of an ordered array of layers with alternating high and low refractive indices. This periodicity leads to an optical band structure that is analogous to the electronic band structure encountered in semiconductor physics: specific bands of wavelengths (the stop bands) are perfectly reflected. Here, we present a minimal model for optical band structure in a periodic multilayer structure and solve it using recursion relations. The stop bands emerge in the limit of an infinite number of layers by finding the fixed point of the recursion. We compare to experimental data for various beetles, whose optical structure resembles the proposed model. Thus, using only the phenomenon of interference and the idea of recursion, we are able to elucidate the concept of band structure in the context of the experimentally observed high reflectance and iridescent appearance of structurally colored beetles.

1.
N. W.
Ashcroft
and
N. D.
Mermin
,
Solid State Physics
(
Harcourt
,
Orlando
,
1976
).
2.
M. F.
Land
, “
The physics and biology of animal reflectors
,”
Prog. Biophys. Mol. Biol.
24
,
75
106
(
1972
).
3.
P.
Vukusic
and
J. R.
Sambles
, “
Photonic structures in biology
,”
Nature
424
,
852
855
(
2003
).
4.
S.
Kinoshita
,
S.
Yoshioka
, and
J.
Miyazaki
, “
Physics of structural colors
,”
Rep. Prog. Phys.
71
,
076401
1
(
2008
).
5.
A. E.
Seago
,
P.
Brady
,
J.
Vigneron
, and
T. D.
Schultz
, “
Gold bugs and beyond: a review of iridescence and structural colour mechanisms in beetles (coleoptera)
,”
J. R. Soc., Interface
6
,
S165
S184
(
2009
).
6.
L.
Biró
and
J.
Vigneron
, “
Photonic nanoarchitectures in butterflies and beetles: Valuable sources for bioinspiration
,”
Laser Photonics Rev.
5
,
27
51
(
2011
).
7.
G. S.
Smith
, “
Structural color of Morpho butterflies
,”
Am. J. Phys.
77
,
1010
1019
(
2009
).
8.
A. F.
Turner
and
P. W.
Baumeister
, “
Multilayer mirrors with high reflectance over an extended spectral region
,”
Appl. Opt.
5
,
69
76
(
1966
).
9.
L.
Rayleigh
, “
On the reflection of light from a regularly stratified medium
,”
Proc. R. Soc. London
93
,
565
577
(
1917
).
10.
A. F.
Huxley
, “
A theoretical treatment of the reflexion of light by multilayer structures
,”
J. Exp. Biol.
48
,
227
245
(
1968
).
11.
S.
Kinoshita
,
Structural Colors in the Realm of Nature
(
World Scientific
,
Singapore
,
2008
).
12.
V. K.
Ignatovich
, “
The remarkable capabilities of recursive relations
,”
Am. J. Phys.
57
,
873
878
(
1989
).
13.
P.
Vukusic
and
D.
Stavenga
, “
Physical methods for investigating structural colours in biological systems
,”
J. R. Soc., Interface
6
,
S133
S148
(
2009
).
14.
P.
Vukusic
,
J. R.
Sambles
,
C. R.
Lawrence
, and
R. J.
Wootton
, “
Quantified interference and diffraction in single Morpho butterfly scales
,”
Proc. R. Soc. London
266
,
1403
1411
(
1999
).
15.
J. A.
Noyes
,
P.
Vukusic
, and
I. R.
Hooper
, “
Experimental method for reliably establishing the refractive index of buprestid beetle exocuticle
,”
Opt. Express
15
,
4351
4358
(
2007
).
16.
S.
Yoshioka
and
S.
Kinoshita
, “
Direct determination of the refractive index of natural multilayer systems
,”
Phys. Rev. E
83
,
051917
1
(
2011
).
17.
D. G.
Stavenga
,
B. D.
Wilts
,
H. L.
Leertouwer
, and
T.
Hariyama
, “
Polarized iridescence of the multilayered elytra of the Japanese jewel beetle, Chrysochroa fulgidissima
,”
Philos. Trans. R. Soc. London, Ser. B
366
,
709
723
(
2011
).
18.
A.
Lipson
,
S. G.
Lipson
, and
H.
Lipson
,
Optical Physics
(
Cambridge U.P.
,
Cambridge
,
2011
).
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