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Topic Name: A fabric with vision:Flexible lensless camera from web of light-detecting fibers
Category: Nanofabrication
Research persons: Yoel Fink , Associate Professor of Materials Science ,MIT
Location: Cambridge, United States
Details
Imagine a soldier's uniform made of a special fabric that allows him to look
in all directions and identify threats that are to his side or even behind him.
In work that could turn such science fiction into reality, MIT researchers have
developed light-detecting fibers that, when weaved into a web, act as a flexible
camera.
Fabric composed of these fibers could be joined to a computer that could
provide information on a small display screen attached to a visor, providing the
soldier greater awareness of his surroundings. The researchers, led by Associate
Professor Yoel Fink of the Department of Materials Science and Engineering (DMSE),
emphasize that while such an application and others like it are still only
dreams, work is rapidly progressing on developing fabrics capable of capturing
images. In a recent issue of the journal Nanoletters, the team reported what it
called a "significant" advance: using such a fiber web to take a rudimentary
picture of a smiley face.
"This is the first time that anybody has demonstrated that a single plane of
fibers, or 'fabric,' can collect images just like a camera but without a lens,"
said Fink, corresponding author of the Nanoletters paper. "This work constitutes
a new approach to vision and imaging." Our eyes are a great example of Nature's
approach to imaging: they involve a highly sophisticated and localized organ
made in part of a delicate lens.
Technologists have mimicked this approach in cameras, telescopes and
even microscopes. But lenses of natural or man-made origin have a limited field
of view, and are susceptible to damage, leading to the loss of the imaging or
seeing capacity altogether. Optical fiber webs, in contrast, provide a
distributed imaging capability provided by the entire surface of a fabric, which
is in principle much more robust to damage and "blindness." If one area is
damaged, other fibers can still function, extracting the image. "We are saying,
'instead of a tiny, sensitive object [for capturing images], let's construct a
large, distributed system,'" said Fink, who is also affiliated with MIT's
Research Laboratory of Electronics (RLE), the Center for Materials Science and
Engineering (CMSE) and Institute for Soldier Nanotechnologies (ISN). "While the
current version of these fabrics can only image nearby objects, it can still can
see much farther than most shirts can," he added. Nested Detection Layers The
new fibers, less than a millimeter in diameter, are composed of layers of
light-detecting materials nested one within another. Those layers include two
rings of a semiconductor material that are light sensitive, each ring only 100
billionths of a meter across. Four metal electrodes contact each of the rings,
extending along the length of the fiber, for a total of eight. Each
semiconductor ring with its attached electrodes is in turn encased in rings of a
polymer insulator that separate it from its neighbor. The team starts with a
macroscopic cylinder, or preform, of these elements. That preform is placed into
a special furnace that melts the components, carefully drawing them into
miniscule fibers that retain the original orientation of the various layers. The
process can produce many meters of fiber.
Fink's team demonstrated the power of their approach by placing an object - a
smiley face - between a light source and a small swatch of fabric composed of
the fibers that was in turn connected to an external amplifying electrical
circuit and computer. The individual fibers measure the intensity of the light
illuminating them and convert it to an electrical signal. Importantly, they are
also designed to differentiate between light at different wavelengths or colors.
A mesh of fibers is then deployed to measure light intensity distribution at
different wavelengths across a large area. In the current work, the smiley face
was illuminated with light at two separate wavelengths. This generated a
distinct pattern on the fabric mesh that was then fed into a computer. From
there, an algorithm described earlier by the Fink team in Nature Materials
assimilates the data to create a black-and-white image of the object on a
computer screen.
First author Fabien Sorin, a postdoctoral associate in RLE, DMSE and ISN,
said that as the individual fibers become more sophisticated, it is possible to
envision fabrics with more intriguing and complex functionalities, such as ones
capable of producing crisper images in color. "It is exciting to merge
nanotechnology, which is at the forefront of modern science, with textiles and
fabrics, one of man's oldest technologies," Sorin said. Sorin's and Fink's
colleagues on the work are Ofer Shapira, also a postdoctoral associate in RLE
and ISN; Ayman F. Abouraddy of the University of Central Florida; Matthew
Spencer of MIT's Department of Electrical Engineering and Computer Science;
Nicholas D. Orf of RLE, DMSE and ISN; and John D. Joannopoulos, director of the
ISN and MIT's Francis Wright Davis Professor of Physics.
This work was supported by the Army Research Office through the ISN, the
National Science Foundation through the Materials Research Science and
Engineering Center Program, the Defense Advanced Research Projects Agency and
the Department of Energy.
About the researcher :
Yoel Fink
Associate Professor of Materials Science
MacVicar Faculty Fellow
B.Sc. Chemical Engineering,
Technion - Israel Institute of Technology, 1994
B.A. Physics, Technion - Israel Institute of Technology, 1995
Ph.D. Materials Science, MIT, 2000
Professor Fink's research interests are in the theory, design, fabrication
and characterization of multimaterial multifunctional fibers and fiber
assemblies. These exciting new materials are composed of conductors,
semiconductors, and insulators with 10's-of-nanometers feature sizes. While
sharing the basic semiconductor device attributes, they are processed using
conventional fiber processing approaches thus yielding kilometers of precisely
controlled fiber structures with engineered electronic, optical, thermal, and
acoustic properties. Prof. Fink's research has led to entirely new classes of
fiber devices including: wavelength-scalable hollow-core photonic bandgap
transmission fibers; high-Q Fabry Perot fiber resonators; transverse surface
emitting fiber lasers; and thermal and optical fiber detectors and fiber array
systems. He was a recipient of the Weizmann Institute Amos De-Shalit Foundation
Scholarship in 1992, was awarded the Hershel Rich Technion Innovation
Competition in 1994, was a recipient of the Technology Review Award for the 100
Top Young Innovators in 1999, and was awarded the National Academy of Sciences
Initiatives in Research Award for 2004. Professor Fink is a co-founder of a
startup company, OmniGuide Inc (2000), and serves on its Board of Directors. He
is the coauthor of more than 40 journal articles, and holds eighteen issued U.S.
patents on photonic fibers and devices.
Contact information :
Yoel Fink
Room 13-5013 77 Mass. Ave.
Cambridge MA 02139
phone : 617-258-6113
Fax : 17-452-3432
Email : yoel@mit.edu
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