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Light Joins Nanoparticles into New Materials

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A low-power laser — similar to the common office laser pointer — can cause gold and carbon nanoparticles to assemble into long chains that follow the laser beam as it moves.

Researchers from Argonne National Laboratory shined a low-power laser into a solution of gold and carbon nanoparticles suspended in water. Unexpectedly, they found that the carbon nanoparticles decomposed or deformed to create a kind of "glue" that enabled the creation of long gold-and-carbon chains that assembled continuously wherever the laser was pointed.


John Bahns, Subramanian Sankaranarayanan, Liaohai Chen and Stephen Gray find new ways to assemble nanoparticles. (Image: Argonne National Lab)

"It's possible that we could use this method to encapsulate pharmaceutical agents for new drug delivery systems or build cathodes with very large surface areas for use in batteries," said John Bahns, a physicist from Argonne who led the invention of the technology. "It could potentially help us find better materials that could be used in everything from catalysts to semiconductors; the possibilities are endless."

This new technique for materials design, known as optically directed assembly (ODA), could provide scientists and inventors with an uncharted route to new materials, technologies and even treatments for diseases. "It's incredibly exciting to think about the vast world of technology that could result from people using ODA," said Liaohai Chen, who helped to develop the technology. "This is just the very beginning; we really don't even know yet all the things that might be possible."

The research leading to the discovery of ODA sought to develop new methods for imaging dynamic biological processes in living systems. "ODA provides a new way to encapsulate metal particles with inert carbon, which can be harnessed to generate imaging probes for studies of biological systems important to bioenergy research or medical diagnostics," Chen said. "ODA opens a new avenue to synthesize a new generation of nanoparticle-based imaging probes especially for the metal isotopes and therapeutic agents with a simple, inexpensive, safer and greener energy efficient process."

The difference between ODA and other light-based experiments in materials design lies in the fact that ODA involves the creation of what Chen called a "structure within a structure." Rather than creating a completely continuous material like a sheet of aluminum foil, ODA forms a larger coherent structure from the individual nanoparticles.

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"You can think of it like going to the beach and pointing a stick at the sand and then all of a sudden having pebbles gather and join together wherever you decided to point the stick," Chen said.

"The laser basically acts kind of like a pen, as opposed to a stylus, creating a thread of gold and carbon as it's moved along," said Subramanian Sankaranarayanan, a nanoscientist at Argonne who collaborated on the research. "It surprised us that such a low-power laser could have such a big effect."

Sankaranarayanan and Stephen Gray of Argonne's Center for Nanoscale Materials have also developed a predictive computational model of the ODA phenomenon.

Optically directed assembly works because the laser heats up the spot onto which it is focused, causing a phenomenon known as "convective flow" in which the solution travels around the hot spot. The action of the flow combined with laser heating brings the particles together, creating the filaments.

The discovery of the ODA technique happened completely by accident. Bahns and Chen were investigating carbon in soil by using a technique called Raman spectroscopy.

The researchers added gold nanoparticles to their sample because these particles are known to boost Raman signals. Because Raman spectroscopy requires the use of a laser, the researchers surprisingly found that gold-carbon chains would form wherever they moved the laser. "It looked almost like an Etch-a-Sketch," Chen said.

Based on the researchers' observations, ODA can also provide a new way to encapsulate metal particles with inert carbon, which researchers believe will eventually allow for the creation of new probes that would investigate the uptake of different molecules by both human and plant tissues.

Gray said ODA helps to bridge a gap that has existed in materials design between structures of different sizes. "There's a grand challenge to extend nanoscale phenomena to the millimeter level," Gray said. "ODA works best in the region between the two called the 'mesoscale,' and so we believe that we have a lot of different opportunities to explore with it."

For more information, visit: www.anl.gov

Published: March 2011
Glossary
nano
An SI prefix meaning one billionth (10-9). Nano can also be used to indicate the study of atoms, molecules and other structures and particles on the nanometer scale. Nano-optics (also referred to as nanophotonics), for example, is the study of how light and light-matter interactions behave on the nanometer scale. See nanophotonics.
raman spectroscopy
Raman spectroscopy is a technique used in analytical chemistry and physics to study vibrational, rotational, and other low-frequency modes in a system. Named after the Indian physicist Sir C.V. Raman who discovered the phenomenon in 1928, Raman spectroscopy provides information about molecular vibrations by measuring the inelastic scattering of monochromatic light. Here is a breakdown of the process: Incident light: A monochromatic (single wavelength) light, usually from a laser, is...
AmericasArgonne National LaboratoryBiophotonicscarbon nanoparticlesdrug delivery systemsgold nanoparticlesIllinoisImagingJohn BahnsLiaohai Chenlow-power laserMaterialsnanonanoparticle-based imaging probesoptically directed assemblyOpticsRaman spectroscopyResearch & TechnologyStephen GraySubramanian SankaranarayananLasers

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