Various
forms of metamaterial
have generated a lot of scientific attention in the past few decades. Some
exciting “potential” applications include the well-publicized invisibility
cloak (Thanks to Harry Potter). As you may know already, metamaterial gains its
bizarre optical property (such as negative index of refraction) by its internal
composition or structure, rather than its original physical property. Most
metamaterial has its magic only in specific wavelength region and this
wavelength region is correlated to how small you can make the internal
structures of the metamaterial. This is exactly why almost all the research on
metamaterial focuses on THz region since THz has very long wavelength and we do
not need to make the structures awfully small to concoct the magic (I did read
some articles about “universal metamaterials”, but it seems a long way to go.
Let’s dream of that coming in CLEO 2012).
Digging
into more details, you can have 2D or 3D metamaterial depending on your
applications. 2D metamaterial – or so called metamaterial tiles (m-tiles) –
seems to make a huge leap in guiding the advance in the invisibility cloak and sensing
platform. And they are easier to make (through the help of photo-lithography,
or micro-machining on the surface). With this powerful combination, a booming
in this field seems inevitable. Let us take a peek of its potential application
in invisibility cloak first:
It
is realized that for a TE plane wave, it is possible to have a perfect
invisibility cloak providing that the metamaterial has the right permittivity
and permeability. However this cloak has to have circular inner and outer
boundaries. As far as we know, it is very difficult to make exact circular
cloak even with nowadays technology. To get around it, certain compromise has
to be made. Instead of using hollow sphere or cylinder, we can use hollow
polyhedral, each facet of which is made by m-tiles. Having this idea in mind,
research group in Germany
carried out a simulation
study, and the result is really promising. Polyhedral made by m-tiles will
actually give quite satisfactory results, and it can hide the structure within
it very well (figure 1). In some circumstance, you can even rotate the
polyhedral without losing its cloaking magic.
 |
| Figure 1. An invisibility cloak made by a faceted dodecahedral. This simulation shows that the plane wave can propagate through it without too much distortion and objects can be hidden inside the dodecahedral. Courtesy of Oliver Paul, Yaroslav Urzhumov, Christoffer Elsen, David Smith, and Marco Rahm. |
The
powerful units of m-tiles have actually simple internal structures. Described
in great details in this article,
you can easily change (tune) its optical property by changing its size and
shape. As shown as an example on figure 2, three hexagonal m-tiles of slightly
different structures have different absorption peaks in THz region. This “easy
to fabricate and tune ability” makes m-tiles more and more popular in the
research world. Considering making these tiles on a flexible film, you can
actually fold them into a functional shape with even more interesting
applications. And maybe one day we will have some advanced mosaics made of
various m-tiles.
 |
| Figure 2. Different shapes of Hexagonal m-tiles. Each side of the structure is ranging from a few um to tens of um. By slightly modifying the structures, each of them absorbs different THz frequency. This flexibility makes m-tiles very versatile. Courtesy of Christopher M. Bingham, Hu Tao, Xianliang Liu, Richard D. Averitt, Xin Zhang, and Willie J. Padilla in Optics Express 16 23 18565 (2008). |
How about getting a step
further -- making these m-tiles on the paper and transforming them to biosensor
platforms? In a nutshell, researchers
from Tufts University and Boston University use micromachining to fabricate
micro-stencils on silicon nitride film. These micro-stencils have many of
m-tiles on it. With the help of micro-stencils, they then imprint the pattern
of the m-tiles on the paper by spraying on the paper substrates using electron
beam evaporation (figure 3). Using this way, you can make as many m-tiles as you want! Now,
this sensor is ready to be radiated by THz radiation. Since paper is relatively
transparent in THz region, it is a very good substrate (a disposal one). Once
the molecules have attached to the m-tiles, they will change the electric capacity
of each m-tile. This change of capacity will reflect on the absorption peak of
the m-tiles. And this makes it a good sensor for various molecules. In fact,
this is quite a new way to sense the molecules. It can achieve the sensitivity
of ~ mmole/L concentration. Not bad as a paper-based sensor!
 |
| Figure 3. Using micro-stencils to imprint as many m-tiles as you want on the paper! The inset shows how the absorption spectra of m-tiles are modified when different amounts of the molecules (in this case, urea) are attached to them. Courtesy of Hu Tao , Logan R. Chieffo , Mark A. Brenckle , Sean M. Siebert , Mengkun Liu , Andrew C. Strikwerda , Kebin Fan , David L. Kaplan , Xin Zhang , Richard D. Averitt , and Fiorenzo G. Omenetto in Adv. Mater., 23, 3197–3201 (2011). |
In the near future, more
applications of m-tiles can be seen, indeed.
Trip
note:
 |
| Figure 4. The poster behind OSA booth in POEM 2011, Wuhan, China. Energetic student chapter of China promoted OSA nicely. Felt so warm when I saw this. |
DISCLAIMER
The
opinions expressed herein are those of the author and do not represent
the Optical Society of America (OSA) or any OSA affiliate.
