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Measuring Excitement for Carbon Nanotubes

Studying light pulses in nanoscale molecules brings scientists closer to understanding properties that may lead to a multitude of applications

Image showing ball and stick model of two crossing carbon nanotubes on a graphite surface.

Ball and stick model of two crossing carbon nanotubes on a graphite surface.
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February 10, 2009

Carbon is the fourth most abundant element in the universe by weight, and without it, there would be no life on Earth. Depending on its crystal structure--how its atoms bond together--carbon can form several different substances, ranging from sooty coal to glittering diamonds to slippery-smooth graphite.

Slice a chunk of graphite into a flat, single-atom thick sheet, and you get another form of carbon: graphene. Take a sheet of graphene and roll it up like a newspaper, and you get a carbon nanotube (CNT).

CNTs are nanoscale molecules made up of large numbers of carbon atoms, each bonded to three other atoms in a hexagonal (six-sided) pattern, resembling a roll of chicken wire. The pattern can be aligned with the tube's central axis, or it can be twisted. Although a CNT may reach a few centimeters in length, the entire tube is only a few nanometers across, or about 100,000 times thinner than a human hair. At this size, it behaves as if it were one-dimensional.

Promising Properties

So much for the what. But why are CNTs making headlines in fields as diverse as aerospace, opto-electronics and bio-medicine? In a word, properties. Because of their superior structural, chemical, optical and electrical properties, carbon nanotubes are among the most promising candidates for use in tomorrow's ever-shrinking technology.

Mechanically, CNTs are five to 50 times stronger than steel, even though they are incredibly small and light. They also conduct heat extremely well. But it's their optical and electrical characteristics that have many scientists and engineers proposing applications ranging from flexible electronics and photovoltaics, to sensing and fluorescent markers in life sciences.

"CNTs have potential for complementing or replacing many current technologies," said Oscar O. Bernal, NSF program director for condensed matter physics. "For instance, they could one day become the main components in lighting devices and consumer electronics. They could represent savings in energy usage and would have the advantage of being very small, allowing miniaturization beyond current limits."

According to Bernal, understanding how particles move through CNTs is one of the necessary steps in the process of developing new applications.

Tobias Hertel, chair for physical chemistry at the University of Würzburg, is developing an experimental tool to study the unique light-emitting properties of CNTs. Hertel began the work while an associate professor at the department of physics and astronomy at the Vanderbilt Institute of Nanoscale Science and Engineering (VINSE), and is supported by a continuing grant from NSF.

Hertel, along with other scientists from Italy and Germany, recently published an article in Nature Physics, entitled, "Size and mobility of excitons in (6, 5) carbon nanotubes," which looks at how photons travel through a semiconductor type of CNT.

"CNTs become semiconducting or metallic depending on their specific diameter and twist," said Hertel. "In this case, we chose a chiral type nanotube, with chains of atoms curled like a corkscrew."

Chiral CNTs can be visualized as twisting a piece of chicken wire so that one hexagon overlaps another on both a different row AND a different column of the pattern. The amount and direction of twist in a CNT can be coded as (n, m), where n is the number of rows and m is the number of columns from the initial atom to the overlapping atom.

Pumping Photons

In order to study a single type of CNT, the scientists first learned how to separate them. Then, using a process called optical pumping, they flashed extremely fast laser light pulses (just femto-seconds in length) through the CNTs.

"Using these ultra-short laser pulses, we can study how energy pumped into the material is redistributed--that is, we learn about how the energy moves through the tubes," Hertel said."

Specifically, the scientists measured optical transitions, or changes in energy. "Say you ride an elevator to the top of a skyscraper: This takes energy, so you have undergone a transition from a low energy state to a high energy state," Hertel explained. "In carbon nanotubes, the transitions we studied also cost energy, which we provided in the form of photons, or light

The photons pumped into the CNTs created something known as an exciton. "Excitons are a type of higher energy state inside a solid body, in which a negatively charged electron is bound to a positively charged particle in much the same way that an electron can be tied to an atom," Hertel explained.

"The size of the exciton determines how it behaves," said Hertel. "For example, if you had a huge ship in a canal, it could move either upstream or downstream. However if the ship was tiny, it could also go sideways across the canal. Just as the size of a ship plays a decisive role for how it can move about in the canal, the size of an exciton affects its motion along a CNT."

Measuring Excitons

The scientists measured the size of the excitons by studying how many would fit into a nanotube. "Say we had a one-gallon sized container filled with marbles," Hertel said. "If we wanted to know how big each marble is, we could simply count the number of marbles in the container." So, for example, if there were 128 marbles, each one would take about as much space as one fluid ounce, since there are 128 fluid ounces in a gallon.

"We found the excitons to be of similar size as the width of the nanotubes, which means that they can either travel forward or backwards in the tubes but not sideways, similar to the big ship in the canal," Hertel said. "Theory had predicted only slightly smaller exciton size than what we observed, but it was nevertheless surprising to find they were so large. We interpret this as a manifestation of the truly one-dimensional character of excitons in CNTs."

In addition to size, the scientists studied the mobility of the excitons. "Mobility is crucial because it allows us to better understand what can happen to an exciton over its lifetime," Hertel explained. "If excitons have a large mobility, they are likely to travel all the way to the ends of CNTs--where some 'bad' things (like non-radiative decay) may happen to them. But we found that the mobility is actually rather small and that excitons don't travel all that far during their lifetime."

Theoretical predictions of exciton behavior in such systems are still rather difficult and need to be corroborated by experiments, Hertel believes.

Questions remain for the scientists. "Exploring the effect of the environment on exciton size and mobility is the next step," said Hertel. "Can we tailor the environment to alter the exciton size and mobility in a desired way?"

--  Holly Martin, National Science Foundation

Tobias Hertel

Related Institutions/Organizations
Vanderbilt University


Related Programs
Condensed Matter Physics

Related Awards
#0606505 Pump-Probe Excitation Spectroscopy of Carbon Nanotubes

Total Grants

Photo showing two glass tubes filled with blue and purple liquid.
Two glass tubes filled with blue and purple liquid.
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Image of a blue/red pattern on a hexagonal overlay.
Wavefunction of the lowest dipole allowed exciton in a nanotube.
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Image showing a ball and stick tunneling microscope composite image of carbon nanotube.
Ball and stick scanning tunneling microscope composite image of a single wall carbon nanotube.
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Image showing ball and stick model of sodium cholate suspended carbon nanotube.
Ball and stick model of a sodium cholate suspended carbon nanotube.
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