Iridescences: The
Physical Colors of Insects
Serge Berthier
Springer International, Dordrecht, The Netherlands
2007; 160 pp.
Price: $111.00 (hardcover)
ISBN-10: 0-387-34119-6
Iridescences:
The Physical Colors Of Insects
was written
by Serge Berthier, a French physicist and materials scientist with a
passion for beautiful insects. Iridescence, or more specifically,
structural colors, are produced by refraction from microstructures
smaller than the wavelength of light, such as the rainbow effect
produced by compact discs. The gorgeous blue in Morpho
butterflies and the bright metallic gold of many tropical beetles
are the result of submicron chitinous structures in the cuticle.
These structural, refractive mechanisms of generating color are
fundamentally different from the more familiar and intuitive
mechanism of coloration via pigment, or the differential absorption
of wavelengths of light by pigment molecules. In addition to being
an important aspect of insect natural history, structural colors are
of interest to physicists and materials scientists because many of
the tiny structures responsible for some of the more impressive
insect phenomena are still impossible to fabricate. In some cases,
the study of insect structural colors has revealed optical phenomena
that were never imagined or characterized by physicists. Berthier
explores and explains color-generating structures and mechanisms in
insects, as well as other relevant topics in natural history and
biological optics.
The
most useful and unique portion of the book is the three chapters
detailing the impressive array of structures that generate color in
beetles and butterflies. Although this information is scattered
throughout the literature, to my knowledge, this is the first time
it has been assembled in one place using clear, specific biological
examples. There is one chapter each on one-, two-, and
three-dimensional structural colors that explains the very different
physical mechanisms by which each dimension of geometry produces
color, with photographs and examples of each type in insects.
In addition to this core information, the book
contains chapters on color space and color theory, the anatomy of
butterfly wings and beetle cuticle, the natural history of butterfly
coloration, insect thermoregulation via pigments and structural
colors, and a primer on biological pigments. The rest of the
material in the book is helpful, but it can be found elsewhere, and
essentially supports and provides background for the chapters on the
dimensional aspects of structural color.
The
major flaw of the book is the generally sloppy editing. First,
strange French–English hybrid grammar appears in almost every
sentence. Most of the time, the important ideas are communicated,
and the French flavor occasionally adds a little fun to the
narrative, but it was often a struggle to read through the awkward
phrasings and then parse what the author meant. Occasionally, the
careless translation obscures real physical meaning, such as the
author’s repeated use of the term “dispersion” where he apparently
means “diffusion”—these terms have physical definitions in English
that are evidently different from the French cognates. In another
example, the term “photonic microscope” appears throughout the book,
which at first I thought might be a sophisticated piece of physics
equipment I’d never heard of, but evidently means “light
microscope.” In addition, the editing of the figures is
problematic—in several captions, panels are labeled “top” and
“center” when they are sitting left and right of one another, and
vice versa. Other figures are miscaptioned.
The
book strangely has no reference section, although the scientific
work of other authors is implicitly discussed. For instance,
Berthier describes a concentration gradient model of butterfly
eyespot development that is evidently from the work of Fred Nijhout
and others, but those authors are never mentioned in the main text
or any bibliography. This is problematic not only because these
ideas should be properly acknowledged, but also because it is
difficult for readers to know where to turn if they would like more
information about a topic or to verify the author’s claims.
Underneath the sometimes awkward translation and
editing problems, however, is a very good introduction and reference
for biologists who are interested in the optical aspects of their
study organisms, as well as a primer in animal diversity and
biological mechanisms for physical scientists. On a second reading,
after deciphering the translation and captioning issues, I realized
what a valuable collection of physics, biology, and unpublished
micrographs this work could be as a resource for scientists
interested in the interface of photonics and biology, or as a text
for a seminar course on the subject.
The
many photographs of butterfly scales in transmission illumination,
immersed in index-matching fluid, and in SEM are an invaluable
collection that would take many hours or days to assemble from other
sources, and in many cases may not be available in the literature.
These photographs are generally of very high quality, and are
beautifully reproduced on the book’s glossy paper. In most cases,
the photographs are more informative than the text in understanding
the topics at hand. Especially effective and useful are the nested
photographs of the same cuticular structure shown at several
different size scales. Having these marvelous photographs collected
in a single place is probably worth the book’s price for scientists
interested in this topic.
I
found most of the physical and mathematical explanations in the text
to be accessible to a physics-minded biologist. For most of the
optical subjects discussed, there is a “back of the envelope”
intuitive diagram of a given phenomenon, as well as equations to
describe the phenomenon, although the author avoids long
mathematical derivations. This approach provides some useful
physical insight to biologists who have likely forgotten any
background they may have had in matrix math, but it also gives
context and an analytical starting point to the physicists in the
audience.
This book could work well as the foundation of an
interdisciplinary graduate seminar or advanced undergraduate course
on structural color and photonics, as long as the editing and
referencing issues were considered beforehand. It would also be
useful to people working at the interface of physics and biology, as
a reference and source of photographic examples of many different
biological optical phenomena, or as an introduction to these topics
for someone with traditional biology training who hopes to learn
some optics, and vice versa.
Alison Sweeney
California NanoSystems Institute
University of California
Santa Barbara, CA, 93106
E-mail:
sweeney@lifesci.ucsb.edu
American Entomologist
Vol. 54, No.3, Fall 2008
