It's crazy wonderful. Felice Frankel helps MIT students look at their work in a whole new way.
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| © Photograph by Felice Frankel Frankel used a scanning electron microscope to take this color-corrected photograph of blue morpho butterfly wings. |
By Catherine Zuckerman, National Geographic
For the mathematically minded, the clean lines and pleasing logic of
equations can be lovely things to behold. But for the uninitiated, even
the most elegant math might as well be gibberish. The same holds true
for fundamental laws of physics, breakthroughs in biology, and any
number of scientific concepts that are highly complex but also
applicable to everyday life.
So, how do researchers make their work make sense to the public? Welcome to the domain of photographer Felice Frankel.
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| © Photograph by Felice Frankel A more magnified version shows even more detail of the blue morpho butterfly wings, which "appear blue because of the nature of their surfaces, reflecting mostly the blue wavelengths of light," Frankel says. |
A
science devotee with a gift for lively conversation, Frankel is
embedded at the Massachusetts Institute of Technology, where she helps
students find ways to visually depict their ideas. Her new book, Picturing Science and Engineering,
is full of examples of complicated research and data sets rendered in
compelling photographs. The point, Frankel says, is to help scientists
“understand that beautiful images can engage the public.”
Doing
so does not require fancy equipment. Frankel proves this in her first
chapter, called “Flatbed Scanner.” As long as a scanner's resolution can
be controlled, she says, this relatively low-tech tool can capture a
surprising amount of information from something like a piece of agate or
abalone. (Also see how a student took a picture of a single atom.)
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| © Photograph by Felice Frankel Frankel often uses background, like this color palette, as an element in composition. |
“It’s
crazy wonderful. You can see detail you couldn’t see with your eye,”
Frankel says. Flatbed scanners can also capture images of more complex
objects, like petri
dishes or analytical devices, and showcase them in new ways. This often
surprises people, she says, because “most folks use [them] for
documents.”
The book’s other chapters walk readers through the
basics of camera use and lighting, as well as how to use microscopes and
even cell phones to visually represent a concept or to illuminate a
difficult-to-grasp calculation. And in situations where the idea isn’t
photographable, Frankel suggests employing metaphors. For instance, “how
in the world do we talk about quantum mechanics?” she asks. “Even
quantum mechanics physicists have trouble, because it’s highly mathematical.”
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| © Photograph by Felice Frankel "Planning ahead for this photograph of a drop of water," Frankel says, "I anticipated and intended that the background of a color palette would be out of focus with my 105 macro lens. If you look carefully, you can see the focused color grid within the drop." |
To
illustrate the theory’s more counterintuitive principles—such as the
notion that light can behave as both a wave and a particle—she made a
digital picture of a glass apple casting a square shadow. (Physicists do
something similar when they explain quantum mechanics through thought
experiments, like Schrödinger's famous cat.)
Frankel
studied biology and chemistry in college and says science has always
been in her soul, although she refers to herself first as a
photographer.
“As I child, I looked carefully at things, like all
children do,” she says. Now, when she sits down with a student to talk
about visualizing a concept, she begins by asking them to tell her the
most critical thing they want to communicate. If the student can’t
explain it, she sends him or her back to sort it out.
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| © Photograph by Felice Frankel Cracked on the surface of a flatbed scanner, a raw egg is held in place by a bowl. |
“It’s about reducing the ideas down to their essence, and in order to do that, you have to understand it yourself,” she says.
At
the end of the book, a visual index lists dozens of examples of
Frankel’s work, along with the studies the images were published with.
The process is highly collaborative, she says, and “a great deal of
fun.” Though most graduate programs don’t include classes on visual
communication of science and engineering, Frankel hopes that will change
in the future.
“I think this younger generation of scientists understands that the visual is extraordinarily powerful.”
Science photographer Felice Frankel is a research scientist in the department of chemical engineering at the Massachusetts Institute of Technology. She is a fellow of the American Association for the Advancement of Science and a Guggenheim Fellow, and she was a Senior Research Fellow in Harvard University’s Faculty of Arts and Sciences and a Visiting Scholar at Harvard Medical School’s Department of Systems Biology.
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| © Photograph by Felice Frankel "Here’s another example using still images to observe changes over time," Frankel says. The grid shows the Belousov-Zhabotinsky chemical reaction taking place in a petri dish at 11-second intervals over a period of five minutes. |
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