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Birth and Growth of Nanocrystals Observed

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ARGONNE, Ill., Oct. 22, 2010 — Scientists say they have observed, for the first time, nanoparticles growing from the earliest stages of their formation. Nanoparticles’ performance depends on their structure, composition and size, which is why researchers aim to develop ways to control conditions under which they are grown. The breakthrough will affect a wide range of applications including solar-cell technology and chemical and biological sensors.


Nanoparticles growing. (Image: Wenge Yang)


“It's been very difficult to watch these tiny particles be born and grow in the past because traditional techniques require that the sample be in a vacuum and many nanoparticles are grown in a metal-conducting liquid,” said Wenge Yang of the Carnegie Institution's Geophysical Laboratory. “So we have not been able to see how different conditions affect the particles, much less understand how we can tweak the conditions to get a desired effect.”

These researchers work at the Center for Nanoscale Materials and the Advanced Photon Source (APS) — both operated by Argonne National Laboratory — and the High Pressure Synergetic Consortium (HPSynC), a program jointly run by the Geophysical Laboratory and Argonne.

The scientists used high-energy X-rays from the APS to carry out diffraction studies that enabled them to gain information on the crystal structure of the materials. Thanks to the highly brilliant and high penetration of this X-ray source — the largest of its kind in the US — the researchers were able to watch the crystals grow from the beginning of their lives. The atoms scatter very short wavelength X-rays and the resulting diffraction pattern reveals the structure of these unusual particles. Quite often the chemical reaction occurs in a very short time and then evolves. The scientists used highly focused high-energy X-rays and a fast area detector, the key components to make this investigation possible. This is the first time-resolved study of the evolution of nanoparticles from the time they are born.

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HPSynC, is also a part of the Energy Frontier for Research in Extreme Environments (EFree) Center, an Energy Frontier Research Center supported at Carnegie by DoE-BES. One of the missions of this center is to harness new synchrotron radiation techniques for in situ studies of materials structure and dynamics in extreme conditions and thereby to understand and produce new energy materials.

“This study shows the promise of new techniques for probing crystal growth in real time. Our ultimate goal is to use these new methods to track chemical reactions as they occur under a variety of conditions, including variable pressures and temperatures, and to use that knowledge to design and make new materials for energy applications. This is a major thrust area of the HPSynC program that we have launched in partnership with Argonne National Laboratory,” said Russell Hemley, the director of Geophysical Laboratory.

For more information, visit:  www.ciw.edu 



Published: October 2010
Glossary
advanced photon source
An accelerator at the Argonne National Laboratory, providing powerful x-ray beams for materials research applications.
diffraction
Diffraction is a fundamental wave phenomenon that occurs when a wave encounters an obstacle or aperture, causing the wave to bend around the edges and spread out. This effect is most commonly observed with light waves, but it can also occur with other types of waves, such as sound waves, water waves, and even matter waves in quantum mechanics. Wave interaction: Diffraction occurs when a wave encounters an obstacle (e.g., an edge or slit) or a series of obstacles, such as a diffraction...
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.
nanotechnology
The use of atoms, molecules and molecular-scale structures to enhance existing technology and develop new materials and devices. The goal of this technology is to manipulate atomic and molecular particles to create devices that are thousands of times smaller and faster than those of the current microtechnologies.
Advanced Photon SourceAmericasArgonne National Laboratorybiological sensorsBiophotonicsCarnegie InstitutionCenter for Nanoscale MaterialsdiffractionenergyEnergy Frontier for Research in Extreme Environments CenterEnergy Frontier Research Centergreen photonicsHigh Pressure Synergetic Consortiumhigh-energy x-raysIllinoisImagingmetal-conducting liquidnanonanocrystalsnanoparticlesnanotechnologyResearch & TechnologyRussell HemleySensors & Detectorssolar cellsWenge Yang

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